Variable power optical system

ABSTRACT

Liquid lens cells are used in a compound variable power optical system that forms an intermediate image between the object and the final image. A first variable power optical component is located between the object and an intermediate real image. The first variable power optical component varies power to change the magnification of the intermediate real image. A second variable power optical component is located between the intermediate real image and the final image. The second variable power optical component varies power to change the magnification of the final image. At least one of the first and second variable power optical components is stationary on the optical axis and comprises at least two liquids with different refractive properties and at least one variable shape contact surface between the two liquids, with variations in the shape of the contact surface producing a change of optical power in the optical system.

RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 12/753,639, filed Apr. 2, 2010, entitled “VARIABLE POWER OPTICAL SYSTEM,” which is set to issue as U.S. Pat. No. 8,638,496 on Jan. 28, 2014, which claims the benefit of priority of U.S. Provisional 61/168,523 filed Apr. 10, 2009. Each of the applications referenced in this paragraph is hereby incorporated by reference in its entirety so as to make part of this specification.

BACKGROUND

The present invention relates to variable power optical systems.

Some zoom lens designs group the lens used in the design, with one group being used largely for zooming, a second group being used largely for keeping an image in focus, and a third group used to keep the image plane stationary. A fourth group may also be used to form a sharp image. The focusing group may be adjusted for focusing the zoom lens at any focal length position without the need to refocus for other focal lengths of the zoom lens. The zooming group (or “variator”) causes significant magnification change during zooming. The lens group that stabilizes the image plane may also be used to provide magnification.

Desirable features in a zoom lens include high zoom ratio and a wide angle field of view. As the zoom range of a lens system increases, generally the length and weight also increases. Consumer products such as cellular telephones or point-and-shoot cameras are often small and lightweight, so zoom lenses included in those products are constrained by size and weight. Moreover, as the focal length range of a lens system increases, generally focusing problems also increase usually at the wide field of view zoom positions.

SUMMARY

Liquid lens cells comprise two or more fluids in a chamber. The fluids contact to form a surface that is variable by, for example, through electrical nodes. A fluid may be, for example, one or more gases, one or more liquids, or a mixture of one or more solids and one or more liquids. Using liquid lens cells to replace one or more moving lens groups results in additional configuration options for the optical path. Liquid cells can be used in a compound zoom lens system to take advantage of these properties. Many point and shoot cameras and cell phone cameras do not have large amounts of space for a long lens. Using liquid cells in combination with folds or redirection of the radiation axis allows for better zoom lens systems in these small camera packages. Larger cameras can also benefit.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A-1D are optical diagrams of a compound zoom lens system employing six liquid lens cells, with a surface of the liquids being varied to provide a range of zoom positions.

FIGS. 2A-2D are optical diagrams of a compound zoom lens system employing five liquid lens cells, with a surface of the liquids being varied to provide a range of zoom positions.

FIGS. 3A-3D are optical diagrams of a compound zoom lens system employing five liquid lens cells, with a surface of the liquids being varied to provide a range of zoom positions.

FIGS. 4A-4D are optical diagrams of a compound zoom lens system employing four liquid lens cells, with a surface of the liquids being varied to provide a range of zoom positions.

FIGS. 5A-5D are optical diagrams of a compound zoom lens system employing three liquid lens cells, with a surface of the liquids being varied to provide a range of zoom positions.

FIGS. 6A-6D are optical diagrams of a compound zoom lens system employing three liquid lens cells, with a surface of the liquids being varied to provide a range of zoom positions.

FIGS. 7A-7D are optical diagrams of a compound zoom lens system employing two liquid lens cells, with a surface of the liquids being varied to provide a range of zoom positions.

FIGS. 8A-8D are optical diagrams of a compound zoom lens system employing a moving lens group and two liquid lens cells, with a surface of the liquids being varied to provide a range of zoom positions.

FIG. 9 illustrates a block diagram of a camera with a zoom lens.

DETAILED DESCRIPTION

In the following description, reference is made to the accompanying drawings. It is to be understood that other structures and/or embodiments may be utilized without departing from the scope of the invention.

Liquid lens cells can modify an optical path without relying upon mechanical movement of the liquid cell. A liquid lens cell comprising first and second contacting liquids may be configured so that a contacting optical surface between the contacting liquids has a variable shape that may be substantially symmetrical relative to an optical axis of the liquid lens cell. A plurality of lens elements could be aligned along a common optical axis and arranged to collect radiation emanating from an object side space and delivered to an image side space. The liquid lens cell could be inserted into an optical path formed by the plurality of lens elements that are aligned along the common optical axis. The optical axis of the liquid lens cell could be parallel to the common optical axis, or it could be at an angle or decentered to the common optical axis.

Presently contemplated liquid lens systems will have a difference in refractive index of about 0.2 or more, preferably at least about 0.3, and in some embodiments at least about 0.4. Water has a refractive index of about 1.3, and adding salt may allow varying the refractive index to about 1.48. Suitable optical oils may have a refractive index of at least about 1.5. Even by utilizing liquids with higher, lower or higher and lower refractive indices, for example a higher refractive index oil, the range of power variation remains limited. This limited range of power variation usually provides less magnification change than that of a movable lens group. Therefore, in a simple variable power optical system, to provide zooming while maintaining a constant image surface position most of the magnification change may be provided by one movable lens group and most of the compensation of defocus at the image surface during the magnification change may be provided by one liquid cell.

It should be noted that more movable lens groups or more liquid cells, or both, may be utilized. Examples of one or more moving lens groups used in combination with one or more liquid cells is described in U.S. patent application Ser. No. 12/246,224 titled “Liquid Optics Zoom Lens and Imaging Apparatus,” filed Oct. 6, 2008, and incorporated by reference in its entirety.

The size and properties of lens elements used in a system introduce constraints to be considered in designing the lens system. For example, the diameter of one or more lens elements may limit the size of an image formed on an image surface. For lens systems with variable properties, such as a variable power optical system, the optics may change based on variation of the lens elements. Thus, a first lens element may constrain a lens system in a first zoom configuration, while a second lens element constrains the lens system in a second zoom configuration. As an example, the rim rays for a light beam may approach the outer edge of a lens element at one extreme of the zoom range, while being a significant distance from the outer edge of the same lens element at the other extreme of the zoom range.

FIGS. 1A-1D illustrate optical diagrams of a simplified compound variable power optical system that forms an intermediate image 108 and a final image 107. As illustrated the stop 109 is located just after liquid lens cell 104 in the relay portion of the lens. The variable power optical system may be used, for example, with a camera. FIG. 1A illustrates the zoom ratio in the wide position, and FIG. 1D illustrates the zoom ratio in the telephoto position.

The variable power optical system illustrated in FIGS. 1A-1D has no moving lens groups. Instead, the zooming and a constant focus at the final image is accomplished through six liquid lens cells 101, 102, 103, 104, 105 and 106, with each liquid lens cell having a variable surface 111, 112, 113, 114, 115 and 116. A control system may be used to control the variable shape of the contacting optical surface in liquid lens cells 101, 102, 103, 104, 105 and 106.

It is to be understood that liquid lens cells could each comprise multiple surfaces, with the surfaces being controllable and/or fixed. In some embodiments, the liquid lens cells could comprise a combination of two or more liquid cells. A plate may be placed between the combined cells. The plate may have an optical power that may be set as desired for the design. The liquid lens cells may also have plates on the exterior surfaces. In some embodiments, the plates on the exterior surfaces may provide optical power or a folding function. The plates and other lens elements can be spherical or aspherical to provide improved optical characteristics.

The individual lens elements may be constructed from solid-phase materials, such as glass, plastic, crystalline, or semiconductor materials, or they may be constructed using liquid or gaseous materials such as water or oil. The space between lens elements could contain one or more gases. For example normal air, nitrogen or helium could be used. Alternatively the space between the lens elements could be a vacuum. When “Air” is used in this disclosure, it is to be understood that it is used in a broad sense and may include one or more gases, or a vacuum. The lens elements may have coatings such as an ultraviolet ray filter.

Liquids in a liquid lens cell may have a fixed volume, and the shape of the outer surface of the liquid lens cell may be fixed. In the accompanying figures, some of the liquid lens cells are illustrated in a way that suggest variation in the volume of liquids and/or variation in the shape of the outer surface of the liquid lens cell. This also means the vertex points of the surfaces shift axially. The illustrations were generated with computer software without placing constraints on volume or shape of the liquid lens cells. The accompanying figures illustrate the concepts of using liquid lens cells in a variable power optical system, and appropriate modifications may be made for the various liquid lens cells that may be used.

The lens elements illustrated in FIGS. 1A-1D are arranged to form an intermediate image 108. Although the location and size of the intermediate image 108 changes as the zoom position changes, it remains between liquid lens cells 101 and 102. Although FIGS. 1A-1D illustrate an objective optics group followed by a relay optics group, multiple relay optics groups could also be used to achieve higher magnifications. Additional magnification can be achieved with high refractive index fluids.

Using liquid lens cells to replace one or more moving lens groups results in additional configuration options for the optical path. Replacing moving lens groups with liquid lens cells facilitates additional design possibilities. For example, a linear optical design may result in a lens that is longer than desired. The use of liquid lens cells instead of a moving group facilitates the use of optical elements such as folds to redirect the radiation axis and reduce the physical length of a lens. Although the overall length of the optical path through the lens may remain the same, the liquid lens cells may provide strategic space for folding that reduces the length in one or more directions. This allows longer overall lens lengths to be used in smaller camera packages. For example, many point and shoot cameras and cell phone cameras do not have large amounts of space for a long lens. Using liquid cells in combination with folds allows for better lens systems in these small camera packages. Larger cameras can also benefit from reducing the camera package length that would be required for a lens system that did not use folds. Using liquid lens cells may also allow for a smaller diameter, especially towards the front of the lens design and especially for wide field of view positions. Folding in combination with a relatively small front diameter, as compared to conventional moving group zoom lens designs, may provide for more compact and ergonomically shaped camera packages.

FIGS. 2A-2D illustrate optical diagrams of a simplified compound variable power optical system using five liquid cells 121, 122, 123, 124, and 125, with each liquid lens cell having a variable surface 131, 132, 133, 134, and 135. The stop 129 is located just after liquid cell 123 in the relay optics group. The optical system forms an intermediate image 128 and a final image 127.

FIGS. 3A-3D illustrate optical diagrams of a simplified compound variable power optical system using five liquid cells 121, 122, 123, 124, and 125, with each liquid lens cell having a variable surface 131, 132, 133, 134, and 135. This design is similar to the design illustrated in FIGS. 2A-2D, but the stop 129 is located in the objective optics group. This may improve the image quality and may allow for liquid cells with smaller diameters, but may also reduce the relative illumination.

FIGS. 4A-4D illustrate optical diagrams of a simplified compound variable power optical system using four liquid cells 141, 142, 143, and 144, with each liquid lens cell having a variable surface 151, 152, 153, and 154. The stop 149 is located in the relay lens group. The optical system forms an intermediate image 148 and a final image 147.

FIGS. 5A-5D illustrate optical diagrams of a simplified compound variable power optical system using three liquid cells 161, 162, and 163, with each liquid lens cell having a variable surface 171, 172, and 173. The stop 169 is located in the relay lens group. The optical system forms an intermediate image 168 and a final image 167.

FIGS. 6A-6D illustrate optical diagrams of a simplified compound variable power optical system using three liquid cells 161, 162, and 163, with each liquid lens cell having a variable surface 171, 172, and 173. The stop 169 is located in the objective lens group. The optical system forms an intermediate image 168 and a final image 167.

FIGS. 7A-7D illustrate optical diagrams of a simplified compound variable power optical system using two liquid cells 181 and 182, with each liquid lens cell having a variable surface 191 and 192. The stop 189 is located in the objective lens group. The optical system forms an intermediate image 188 and a final image 187.

FIGS. 8A-8D illustrate optical diagrams of a simplified compound variable power optical system using two liquid cells 201 and 202, with each liquid lens cell having a variable surface 211 and 212. The illustrated embodiment also has a moving lens group 203. An intermediate image is formed at image surface 208, between the liquid cells 201 and 202. The configuration of optical elements results in a final image 207 that is larger than the final images obtained in earlier embodiments. This allows the use of a larger image sensor, such as sensors 11 mm to 28 mm and above. A moving lens group is used near the sensor because the diameter of a liquid cell may not be sufficiently large to achieve the desired performance. Of note, the final image 207 is also larger than the rim rays at the liquid lens cell variable surface 211 and 212.

For each of the lens designs shown in FIGS. 1-8, a listing produced by the CodeV optical design software version 9.70 commercially available from Optical Research Associates, Pasadena, Calif. USA is attached hereto as part of this specification and incorporated by reference in its entirety.

The lens designs shown in FIGS. 1-8 provide a relatively high zoom ratio, as can be seen from the range of focal lengths of the lens designs listed in TABLE 1. For example, the lens designs in FIGS. 1-8 respectively provide zoom ratios of about 4.4× (F4/F1=−15.6497/−3.5462), 3.3× (−23.9964/−7.2007), 3.3× (−23.9985/−7.2005), 3.3× (−23.9965/−7.2), 3× (−22.046/−7.351), 3× (−22.0489/−7.3514), 2.8× (−21.9962/−7.8524), and 2.8× (−55.7271/−20.0878).

TABLE 1 Effective Focal Length for Lens Designs Lens Design Figure Position 1 Position 2 Position 3 Position 4 FIG. 1 −3.5462 −5.4545 −8.9999 −15.6497 FIG. 2 −7.2007 −10.3000 −15.4998 −23.9964 FIG. 3 −7.2005 −10.2999 −15.4999 −23.9985 FIG. 4 −7.2000 −10.2999 −15.4990 −23.9965 FIG. 5 −7.3510 −10.2999 −15.4979 −22.0460 FIG. 6 −7.3514 −10.3000 −15.5003 −22.0489 FIG. 7 −7.8524 −10.3484 −15.8485 −21.9962 FIG. 8 −20.0878 −25.9451 −40.0379 −55.7271

FIG. 9 illustrates a block diagram of a camera 100 with a zoom lens 102. FIG. 9 also illustrates a lens control module 104 that controls the movement and operation of the lens groups in lens 102. The control module 104 includes electronic circuitry that controls the radius of curvature in the liquid lens cell. The appropriate electronic signal levels for various focus positions and zoom positions can be determined in advance and placed in one or more lookup tables. Alternatively, analog circuitry or a combination of circuitry and one or more lookup tables can generate the appropriate signal levels. In one embodiment, one or more polynomials are used to determine the appropriate electronic signal levels. Points along the polynomial could be stored in a lookup table or the polynomial could be implemented with circuitry. The lookup tables, polynomials, and/or other circuitry may use variables for zoom position, focus position, temperature, or other conditions.

Thermal effects may also be considered in the control of the radius of curvature of surface between the liquids. The polynomial or lookup table may include an additional variable related to the thermal effects.

The control module 104 may include preset controls for specific zoom settings or focal lengths. These settings may be stored by the user or camera manufacturer.

FIG. 9 further illustrates an image capture module 106 that receives an optical image corresponding to an external object. The image is transmitted along an optical axis through the lens 102 to the image capture module 106. The image capture module 106 may use a variety of formats, such as film (e.g., film stock or still picture film), or electronic image detection technology (e.g., a CCD array, CMOS device or video pickup circuit). The optical axis may be linear, or it may include folds.

Image storage module 108 maintains the captured image in, for example, on-board memory or on film, tape or disk. In one embodiment, the storage medium is removable (e.g., flash memory, film canister, tape cartridge or disk).

Image transfer module 110 provides transferring of the captured image to other devices. For example, the image transfer module 110 may use one or a variety of connections such as, for example, a USB port, IEEE 1394 multimedia connection, Ethernet port, Bluetooth wireless connection, IEEE 802.11 wireless connection, video component connection, or S-Video connection.

The camera 100 may be implemented in a variety of ways, such as a video camera, a cell phone camera, a digital photographic camera, or a film camera.

The liquid cells in the focus and zoom groups could be used to provide stabilization, as described in U.S. patent application Ser. No. 12/327,666 titled “Liquid Optics Image Stabilization,” filed Dec. 3, 2008, incorporated by reference in its entirety. By using non-moving lens groups, folds may be used to reduce the overall size as described in U.S. patent application Ser. No. 12/327,651 titled “Liquid Optics with Folds Lens and Imaging Apparatus,” filed Dec. 3, 2008, incorporated by reference in its entirety. One or more moving lens groups may be used in combination with one or more liquid cells as described in U.S. patent application Ser. No. 12/246,224 titled “Liquid Optics Zoom Lens and Imaging Apparatus,” filed Oct. 6, 2008, incorporated by reference in its entirety.

It is to be noted that various changes and modifications will become apparent to those skilled in the art. Such changes and modifications are to be understood as being included within the scope of the invention as defined by the appended claims.

APPENDIX 1 6 Cell - Stop in Relay CLZ6mmV154patready RDY  THI   RMD GLA CCY THC GLC > OBJ: INFINITY 54544.854546 100 100  1: INFINITY 2.727270 100 100  2: 14.14879 3.802477 879272.380394 100 100 100 ASP: K: 0.000000 KC: 100 IC: YES CUF: 0.000000 CCF: 100 A: −.720017E−05 B: 0.414831E−06 C: −.135762E−06 D: 0.000000E+00 AC: 100 BC: 100 CC: 100 DC: 100  3: −7.06296 0.381818 805470.255560 100 100 100  4: 3.22104 2.659581 100 100  5: −2.69367 1.190376 847000.238000 100 100 100  6: −3.68297 0.054545 100 100  7: 14.67373 2.482293 804000.466000 100 100 100  8: −8.14807 0.054545 100 100  9: 7.07307 1.952670 707993.507318 100 100 100 10: −5.82987 0.471413 863988.297593 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 11: 109.85930 0.054545 100 100 12: 14.24555 0.381818 764643.276857 100 100 100 13: 4.32783 0.553104 100 100 14: 14.95926 0.560085 847000.238000 100 100 100 15: INFINITY 2.316620 ‘OIL_C300’ 100 100 16: −5.45454 4.303096 WATER_SPECIAL 100 100 17: INFINITY 0.675032 847000.238000 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 18: −20.93682 7.400276 100 100 19: INFINITY 0.384519 100 100 20: 51.01092 3.528754 847770.240223 100 100 100 21: −11.69131 0.054545 100 100 22: 11.88534 2.013206 883000.407000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 23: 0.545454e18 2.373760 ‘OIL_C300’ 100 100 24: 3.53429 2.576252 WATER_SPECIAL 100 100 25: INFINITY 0.381818 807872.247485 100 100 100 26: 5.89000 0.502283 100 100 27: -266.23222 0.381818 435000.950000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 28: INFINITY 0.479914 WATER_SPECIAL 100 100 29: −21.81816 0.668418 ‘OIL_C300’ 100 100 30: INFINITY 0.381818 605903.347382 100 100 100 31: 13.59708 2.598559 100 100 32: 32.86662 0.433647 883000.407000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 33: INFINITY 0.652501 WATER_SPECIAL 100 100 34: −6.56824 3.988731 ‘OIL_C300’ 100 100 35: INFINITY 0.381818 708009.281834 100 100 100 GP1: SBSL7_OHARA SPG: PRC: STO: 10.10322 0.105332 100 100 37: 11.25580 0.838296 877863.410092 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 38: −15.21330 0.054545 100 100 39: 8.86303 0.480616 847000.238000 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 40: 11.78157 1.079041 100 100 41: INFINITY 0.000000 100 100 42: INFINITY 0.000000 100 100 43: INFINITY 6.813137 100 100 44: −92.63050 0.813431 804000.466000 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 45: −10.71635 0.054545 100 100 46: 14.73625 0.806783 804000.466000 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 47: −58.02481 0.480685 100 100 48: −10.12677 0.381818 847000.238000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 49: INFINITY 0.788519 WATER_SPECIAL 100 100 50: 4.30909 2.072258 ‘OIL_C300’ 100 100 51: INFINITY 0.381818 847000.238000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 52: 5.56300 0.615890 100 100 53: 14.17436 0.704164 882732.407159 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 54: INFINITY 0.667652 WATER_SPECIAL 100 100 55: 8.35154 4.684489 ‘OIL_C300’ 100 100 56: INFINITY 1.913812 439872.916637 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 57: −6.46148 4.277344 100 100 ASP: K: 0.000000 KC: 100 IC: YES CUF: 0.000000 CCF: 100 A: 0.506790E−03 B: −.278311E−04 C: 0.556342E−06 D: 0.000000E+00 AC: 100 BC: 100 CC: 100 DC: 100 58: INFINITY 0.000000 100 100 IMG: INFINITY 0.000000 100 100 SPECIFICATION DATA FNO 2.95000 DIM MM WL 587.56 546.07 486.13 REF 2 WTW 88  99   77  INI IAN XIM 0.00000 0.00000 0.00000 0.00000 0.00000  YIM 0.00000 1.20000 1.95000 2.55000 3.00000  WTF 1.00000 1.00000 1.00000 1.00000 1.00000  VUX 0.00000 −0.02640 −0.07915 −0.14822 −0.21525  VLX 0.00000 −0.02640 −0.07915 −0.14822 −0.21525  VUY 0.00000 −0.12398 −0.19154 −0.33419 0.17544  VLY 0.00000 −0.06112 −0.24852 −0.30018 −0.32892  POL    N APERTURE DATA/EDGE DEFINITIONS CA APE CIR S2 4.772722 CIR S6 2.378179 CIR S25 2.454543 CIR S26 2.454543 CIR S32 1.849089 CIR S44 3.141815 PRIVATE CATALOG PWL 656.30 589.30 546.10 486.00 ‘OIL_C300’  1.511500  1.515000  1.518000  1.523800 REFRACTIVE INDICES GLASS CODE 587.56 546.07 486.13 WATER_SPECIAL  1.333041  1.334468  1.337129 ‘OIL_C300’  1.515107  1.518002  1.523784 435000.950000  1.435000  1.436102  1.438080 883000.407000  1.883000  1.888148  1.898279 708009.281834  1.708009  1.713943  1.725869 877863.410092  1.877863  1.882944  1.892936 847000.238000  1.847000  1.855385  1.872415 804000.466000  1.804000  1.808101  1.816103 804000.466000  1.804000  1.808101  1.816103 847000.238000  1.847000  1.855385  1.872415 847000.238000  1.847000  1.855385  1.872415 882732.407159  1.882732  1.887877  1.898001 439872.916637  1.439872  1.441023  1.443113 863988.297593  1.863988  1.870851  1.884600 847000.238000  1.847000  1.855385  1.872415 805470.255560  1.805470  1.812905  1.827936 605903.347382  1.605903  1.610034  1.618238 879272.380394  1.879272  1.884753  1.895580 847000.238000  1.847000  1.855385  1.872415 804000.466000  1.804000  1.808101  1.816103 707993.507318  1.707993  1.711314  1.717756 764643.276857  1.764643  1.771166  1.784288 847000.238000  1.847000  1.855385  1.872415 847770.240223  1.847770  1.856087  1.872967 807872.247485  1.807872  1.815568  1.831159 883000.407000  1.883000  1.888148  1.898279 No solves defined in system No pickups defined in system POS 1 POS 2 POS 3 POS 4 ZOOM DATA FNO 2.95000 3.35000 3.80000 4.95000 VUY F1 −0.3725E−09 −0.3725E−09 −0.3725E−09 −0.3725E−09 VLY F1 −0.3725E−09 −0.3725E−09 −0.3725E−09 −0.3725E−09 VUY F2 −0.12398 −0.03700 0.00804 0.07596 VLY F2 −0.06112 −0.00170 0.00988 0.00793 VUY F3 −0.19154 0.01893 0.07201 0.13373 VLY F3 −0.24852 −0.04969 −0.00071 0.00498 VUY F4 −0.33419 0.03915 0.12034 0.19029 VLY F4 −0.30018 −0.05888 −0.02007 −0.00204 VUY F5 0.17544 0.04116 0.15566 0.24153 VLY F5 −0.32892 0.00247 −0.02811 −0.01038 VUX F1 −0.3725E−09 −0.3725E−09 −0.3725E−09 −0.3725E−09 VLX F1 −0.3725E−09 −0.3725E−09 −0.3725E−09 −0.3725E−09 VUX F2 −0.02640 −0.00699 −0.00456 0.00089 VLX F2 −0.02640 −0.00699 −0.00456 0.00089 VUX F3 −0.07915 −0.02145 −0.01230 0.00673 VLX F3 −0.07915 −0.02145 −0.01230 0.00673 VUX F4 −0.14822 −0.04100 −0.02151 0.01581 VLX F4 −0.14822 −0.04100 −0.02151 0.01581 VUX F5 −0.21525 −0.06060 −0.03026 0.02698 VLX F5 −0.21525 −0.06060 −0.03026 0.02698 RSL DEF DEF DEF DEF RDY S16 −5.45454 14.51052 5.47864 3.99889 CCY S16 100 100 100 100 RDY S24 3.53429 4.11891 −15.45452 −7.19061 CCY S24 100 100 100 100 RDY S29 −21.81816 −27.27270 −32.72724 4.76156 CCY S29 100 100 100 100 RDY S34 −6.56824 −22.34212 32.06825 8.14296 CCY S34 100 100 100 100 RDY S50 4.30909 4.36363 6.64074 −6.40897 CCY S50 100 100 100 100 RDY S55 8.35154 −168.55049 −13.42307 −10.90908 CCY S55 100 100 100 100 INFINITE CONJUGATES EFL −3.5462 −5.4545 −8.9999 −15.6497 BFL 0.0076 0.0169 0.0215 −0.0017 FFL 7.5569 6.7811 7.9450 5.5696 FNO −2.9500 −3.3500 −3.8000 −4.9496 AT USED CONJUGATES RED −0.0001 −0.0001 −0.0002 −0.0003 FNO −2.9500 −3.3500 −3.8000 −-4.9500 OBJ DIS 54544.8545 54544.8545 54544.8545 54544.8545 TT 54626.6726 54626.6726 54626.6726 54626.6726 IMG DIS 0.0000 0.0000 0.0000 0.0000 OAL 81.8181 81.8181 81.8181 81.8181 PARAXIAL IMAGE HT 3.0000 3.0000 3.0000 3.0000 THI 0.0079 0.0175 0.0230 0.0028 ANG 40.2295 28.8108 18.4349 10.8509 ENTRANCE PUPIL DIA 1.2021 1.6282 2.3684 3.1618 THI 7.2584 6.5378 8.2006 9.6112 EXIT PUPIL DIA 14.2822 36.5083 83.4015 12.2431 THI 42.1405 122.3202 −316.9028 −60.6007 STO DIA 4.4042 4.4544 4.5854 4.7178 FABRICATION DATA 28-Mar-09 CLZ6mmV154patready ELEMENT RADIUS OF CURVATURE APERTURE DIAMETER NUMBER FRONT BACK THICKNESS FRONT BACK GLASS OBJECT INF 54544.8545 15.5028         2.7273  1 A(1)  −7.0630 CX   3.8025  9.5454  7.3647 879.380  2  −7.0630 CC  3.2210 CC   0.3818  7.3647  4.3828 805.255   2.6596  3  −2.6937 CC  −3.6830 CX   1.1904  3.7488  4.7564 847.238   0.0545  4  14.6737 CX  −8.1481 CX   2.4823  5.5287  5.8038 804.466   0.0545  5   7.0731 CX  −5.8299 CX   1.9527  5.4319  4.9801 707.507  6  −5.8299 CC 109.8593 CC   0.4714  4.9801  4.8432 863.297   0.0545  7  14.2455 CX  4.3278 CC   0.3818  4.7959  4.5761 764.276   0.5531  8  14.9593 CX INF   0.5601  4.6183  4.6686 847.238  9 INF  −5.4545*5   2.3166  4.6686  5.0924 ‘OIL_C300’ 10  −5.4545*5 INF   4.3031  5.0924  6.8467 WATER 11 INF −20.9368 CX   0.6750  6.8467  6.9832 847.238   7.4003 11.5973         0.3845 12  51.0109 CX −11.6913 CX   3.5288 12.1648 12.5246 847.240   0.0545 13  11.8853 CX  0.5455E+18 CC   2.0132 10.4417  9.7860 883.407 14   0.5455E+18 CX  3.5343*6   2.3738  9.7860  5.8667 ‘OIL_C300’ 15   3.5343*6 INF   2.5763  5.8667  4.9091 WATER 16 INF  5.8900 CC   0.3818  4.9091  4.9091 807.247   0.5023 17 −266.2322 CC INF   0.3818  4.3062  4.2243 435.950 18 INF −21.8182*1   0.4799  4.2243  4.1381 WATER 19  −21.8182*1 INF   0.6684  4.1381  4.0043 ‘OIL_C300’ 20 INF  13.5971 CC   0.3818  4.0043  3.9182 605.347   2.5986 21  32.8666 CX INF   0.4336  3.6982  3.7445 883.407 22 INF  −6.5682*3   0.6525  3.7445  3.9819 WATER 23  −6.5682*3 INF   3.9887  3.9819  4.6183 ‘OIL_C300’ 24 INF  10.1032 CC   0.3818  4.6183  4.7178 708.281 APERTURE STOP   4.7178        0.1053 25  11.2558 CX −15.2133 CX   0.8383  4.8014  4.8948 877.410   0.0545 26   8.8630 CX  11.7816 CC   0.4806  5.0013  4.9336 847.238   1.0790 5.0573        0.0000 5.0573        0.0000 5.0573        6.8131 27  −92.6305 CC −10.7164 CX   0.8134  6.2836  6.3734 804.466   0.0545 28  14.7362 CX −58.0248 CX   0.8068  6.3081  6.2181 804.466   0.4807 29  −10.1268 CX INF   0.3818  6.1747  6.2012 847.238 30 INF  4.3091*2   0.7885  6.2012  6.2929 WATER 31   4.3091*2 INF   2.0723  6.2929  6.1437 ‘OIL_C300’ 32 INF  5.5630 CC   0.3818  6.1437  5.9306 847.238   0.6159 33  14.1744 CX INF   0.7042  6.0108  6.1037 882.407 34 INF  8.3515*4   0.6677  6.1037  6.5683 WATER 35   8.3515*4 INF   4.6845  6.5683  7.3324 ‘OIL_C300’ 36 INF A(2)   1.9138  7.3324  7.4857 439.916   4.2773 6.2576      IMAGE DISTANCE =   0.0000 IMAGE INF 6.2576      NOTES Positive radius indicates the center of curvature is to the right Negative radius indicates the center of curvature is to the left Dimensions are given in millimeters Thickness is axial distance to next surface Image diameter shown above is a paraxial value, it is not a ray traced value Other glass suppliers can be used if their materials are functionally equivalent to the extent needed by the design; contact the designer for approval of substitutions. ASPHERIC CONSTANTS $Z = {\frac{({CURV})Y^{2}}{1 + \left( {1 - {\left( {1 + K} \right)({CURV})^{2}Y^{2}}} \right)^{\frac{1}{2}}} + {(A)Y^{4}} + {(B)Y^{6}} + {(C)Y^{8}} + {(D)Y^{10}}}$ ASPHERIC CURV K A B C D A(1)  0.07067741 0.000000 −7.20017E−06  4.14831E−07 −1.35762E−07 0.00000E+00 A(2) −0.15476330 0.000000  5.06790E−04 −2.78311E−05  5.56342E−07 0.00000E+00 REFERENCE WAVELENGTH = 546.1 NM SPECTRAL REGION = 486.1-587.6 NM POS. 1 POS. 2 POS. 3 POS. 4 * ZOOM PARAMETERS *1 = −21.8182 −27.2727 −32.7272 4.7616 *2 = 4.3091 4.3636 6.6407 −6.4090 *3 = −6.5682 −22.3421 32.0682 8.1430 *4 = 8.3515 −168.5505 −13.4231 −10.9091 *5 = −5.4545 14.5105 5.4786 3.9989 *6 = 3.5343 4.1189 −15.4545 −7.1906 INFINITE CONJUGATES EFL = −3.5462 −5.4545 −8.9999 −15.6497 BFL = 0.0076 0.0169 0.0215 −0.0017 FFL = 7.5569 6.7811 7.9450 5.5696 F/NO = −2.9500 −3.3500 −3.8000 −4.9496 AT USED CONJUGATES REDUCTION = −0.0001 −0.0001 −0.0002 −0.0003 FINITE F/NO = −2.9500 −3.3500 −3.8000 −4.9500 OBJECT DIST = 54544.8545 54544.8545 54544.8545 54544.8545 TOTAL TRACK = 54626.6726 54626.6726 54626.6726 54626.6726 IMAGE DIST = 0.0000 0.0000 0.0000 0.0000 OAL = 81.8181 81.8181 81.8181 81.8181 PARAXIAL IMAGE HT = 3.0000 3.0000 3.0000 3.0000 IMAGE DIST = 0.0079 0.0175 0.0230 0.0028 SEMI-FIELD ANGLE = 40.2295 28.8108 18.4349 10.8509 ENTR PUPIL DIAMETER = 1.2021 1.6282 2.3684 3.1618 DISTANCE = 7.2584 6.5378 8.2006 9.6112 EXIT PUPIL DIAMETER = 14.2822 36.5083 83.4015 12.2431 DISTANCE = 42.1405 122.3202 −316.9028 −60.6007 APER STOP DIAMETER = 4.4042 4.4544 4.5854 4.7178 NOTES FFL is measured from the first surface BFL is measured from the last surface

APPENDIX 2 5 Cell - Stop in Relay CLZ6mmMockUpV030 RDY  THI   RMD GLA CCY THC GLC > OBJ: INFINITY 99999.000000 100 100  1: INFINITY 5.000000 100 100  2: 33.62353 6.621981 883000.407000 100 100 100 ASP: K: 0.000000 KC: 100 IC: YES CUF: 0.000000 CCF: 100 A: −.277553E−04 B: −.267993E−06 C: −.150270E−08 D: 0.000000E+00 AC: 100 BC: 100 CC: 100 DC: 100  3: −13.31085 0.700000 661050.306155 100 100 100  4: 6.37292 4.396645 100 100  5: −5.44401 2.014918 883000.407000 100 100 100  6: −7.12104 0.100000 100 100  7: 28.13720 5.541042 839446.436159 100 100 100  8: −15.23126 0.100000 100 100  9: 14.51796 3.332354 738281.492321 100 100 100 10: −9.83471 0.700000 860953.290036 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 11: −3968.83370 0.100000 100 100 12: 42.74776 0.700000 861115.290274 100 100 100 13: 9.17708 1.095588 100 100 14: 79.29350 0.819196 847000.238000 100 100 100 15: INFINITY 4.615594 ‘OIL_C300’ 100 100 16: −10.00000 8.173468 WATER_SPECIAL 100 100 17: INFINITY 1.853444 847000.238000 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 18: −27.09296 12.078175 100 100 19: INFINITY 0.704953 100 100 20: 30.89389 7.184198 847000.238000 100 100 100 21: −30.45239 6.307727 100 100 22: 33.59626 2.189749 435000.950000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 23: INFINITY 2.064722 625000.4500000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 24: 12.00000 6.000000 WATER_SPECIAL 100 100 25: INFINITY 0.700000 847000.238000 100 100 100 26: 8.63792 0.955137 100 100 27: 44.66714 1.316792 857641.272427 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 28: −18.94105 0.700000 501077.524564 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 29: 96.18511 0.700000 645057.380289 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 30: 5.83570 1.751452 700299.511491 100 100 100 31: 16.49959 1.681613 100 100 32: 50.57460 0.855955 847000.238000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 33: INFINITY 1.516909 WATER_SPECIAL 100 100 34: −10.03917 5.461876 ‘OIL_C300’ 100 100 35: INFINITY 4.735879 707563.288626 100 100 100 GP1: SBSL7_OHARA SPG: PRC: STO: 27.16290 0.289884 100 100 37: 30.49181 1.927243 806738.463452 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 38: −16.25619 0.100000 100 100 39: 15.76301 0.940307 850731.427914 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 40: 20.47911 1.978245 100 100 41: INFINITY 0.000000 100 100 42: INFINITY 0.000000 100 100 43: INFINITY 12.495530 100 100 44: 534.96394 1.485181 804000.466000 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 45: −24.31724 0.100000 100 100 46: 25.16770 1.420776 804061.465943 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 47: −425.23853 0.945766 100 100 48: −19.56961 0.700000 847000.238000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 49: INFINITY 1.285776 WATER_SPECIAL 100 100 50: 7.29257 3.803671 ‘OIL_C300’ 100 100 51: INFINITY 0.748062 847000.238000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 52: 8.91789 1.226099 100 100 53: 27.98816 1.163638 883000.407000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 54: INFINITY 1.115954 WATER_SPECIAL 100 100 55: 15.84923 9.140843 ‘OIL_C300’ 100 100 56: INFINITY 2.363658 880278.387006 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 57: −25.64744 4.000000 100 100   ASP: K: 0.000000 KC: 100 IC: YES CUF: 0.000000 CCF: 100 A: −.658801E−04 B: −.117390E−05 C: 0.122063E−07 D: 0.000000E+00 AC: 100 BC: 100 CC: 100 DC: 100 58: INFINITY 0.000000 100 100 IMG: INFINITY 0.000000 100 100

SPECIFICATION DATA FNO 2.95000 DIM MM WL 587.56 546.07 486.13   REF 2 WTW 88  99   77    INI IAN XRI 0.00000 0.00000 0.00000 0.00000 0.00000  YRI 0.00000 2.20000 3.57500 4.67500 5.50000  WTF 1.00000 1.00000 1.00000 1.00000 1.00000  VUX 0.00000 −0.02195 −0.07009 −0.13945 −0.21055  VLX 0.00000 −0.02195 −0.07009 −0.13945 −0.21055  VUY 0.00000 −0.09765 −0.32715 −0.67323 0.31529  VLY 0.00000 −0.05289 −0.25074 −0.56986 −0.81072  POL     N   APERTURE DATA/EDGE DEFINITIONS CA APE CIR S2 8.820000 CIR S6 3.840000 CIR S24 5.700000 CIR S25 5.700000 CIR S26 5.700000 CIR S32 3.970000 CIR S44 5.970000 PRIVATE CATALOG PWL 656.30 589.30 546.10 486.00 ‘OIL_C300’  1.511500  1.515000  1.518000  1.523800 REFRACTIVE INDICES GLASS CODE 587.56 546.07 486.13 WATER_SPECIAL  1.333041  1.334468  1.337129 ‘OIL_C300’  1.515107  1.518002  1.523784 857641.272427  1.857641  1.865074  1.880044 847000.238000  1.847000  1.855385  1.872415 707563.288626  1.707563  1.713355  1.724981 806738.463452  1.806738  1.810875  1.818951 850731.427914  1.850731  1.855452  1.864713 804000.466000  1.804000  1.808101  1.816103 804061.465943  1.804061  1.808163  1.816166 847000.238000  1.847000  1.855385  1.872415 847000.238000  1.847000  1.855385  1.872415 883000.407000  1.883000  1.888148  1.898279 880278.387006  1.880278  1.885672  1.896319 860953.290036  1.860953  1.867968  1.882042 847000.238000  1.847000  1.855385  1.872415 661050.306155  1.661050  1.666156  1.676369 700299.511491  1.700299  1.703558  1.709874 883000.407000  1.883000  1.888148  1.898279 883000.407000  1.883000  1.888148  1.898279 839446.436159  1.839446  1.844017  1.852974 738281.492321  1.738281  1.741849  1.748782 861115.290274  1.861115  1.868125  1.882190 847000.238000  1.847000  1.855385  1.872415 847000.238000  1.847000  1.855385  1.872415 847000.238000  1.847000  1.855385  1.872415 435000.950000  1.435000  1.436102  1.438080 501077.524564  1.501077  1.503352  1.507752 645057.380289  1.645057  1.649078  1.657024 625000.450000  1.625000  1.628300  1.634754 No solves defined in system No pickups defined in system

POS 1 POS 2 POS 3 POS 4 ZOOM DATA FNO 2.95000 3.35000 3.80000 4.95000 VUY F1 −0.3725E−09 −0.3725E−09 −0.3725E−09 −0.3725E−09 VLY F1 −0.3725E−09 −0.3725E−09 −0.3725E−09 −0.3725E−09 VUY F2 −0.09765 −0.04379 −0.03401 −0.02307 VLY F2 −0.05289 −0.01604 −0.00548 −0.00590 VUY F3 −0.32715 −0.12413 −0.08273 −0.05558 VLY F3 −0.25074 −0.07510 −0.03203 −0.02426 VUY F4 −0.67323 −0.23687 −0.14609 −0.09575 VLY F4 −0.56986 −0.17735 −0.07206 −0.04837 VUY F5 0.31529 −0.29148 −0.16691 −0.07431 VLY F5 −0.81072 −0.29414 −0.11706 −0.07292 VUX F1 −0.3725E−09 −0.3725E−09 −0.3725E−09 −0.3725E−09 VLX F1 −0.3725E−09 −0.3725E−09 −0.3725E−09 −0.3725E−09 VUX F2 −0.02195 −0.00921 −0.00629 −0.00465 VLX F2 −0.02195 −0.00921 −0.00629 −0.00465 VUX F3 −0.07009 −0.02746 −0.01732 −0.01243 VLX F3 −0.07009 −0.02746 −0.01732 −0.01243 VUX F4 −0.13945 −0.05310 −0.03102 −0.02159 VLX F4 −0.13945 −0.05310 −0.03102 −0.02159 VUX F5 −0.21055 −0.08078 −0.04462 −0.03032 VLX F5 −0.21055 −0.08078 −0.04462 −0.03032 RSL DEF DEF DEF DEF RDY S16 −10.00000 −62.95483 23.64747 10.56882 CCY S16 100 100 100 100 THI S23 2.06472 4.06474 2.86288 1.80993 THC S23 100 100 100 100 RDY S24 12.00000 14.50000 −23.14755 −13.41063 CCY S24 100 100 100 100 THI S24 6.00000 4.00000 5.20185 6.25480 THC S24 100 100 100 100 RDY S34 −10.03917 −18.81549 −19.11802 42.75679 CCY S34 100 100 100 100 RDY S50 7.29257 8.00000 12.65953 −12.85912 CCY S50 100 100 100 100 RDY S55 15.84923 −34.90475 −25.04955 −19.06975 CCY S55 100 100 100 100   INFINITE CONJUGATES EFL −7.2007 −10.3000 −15.4998 −23.9964 BFL 0.0228 0.0291 0.0372 −0.0049 FFL 12.6465 10.7972 10.6052 4.5958 FNO −2.9500 −3.3500 −3.7999 −4.9495 AT USED CONJUGATES RED −0.0001 −0.0001 −0.0002 −0.0003 FNO −2.9500 −3.3500 −3.8000 −4.9500 OBJ DIS 99999.0000 99999.0000 99999.0000 99999.0000 TT 0.1001E+06 0.1001E+06 0.1001E+06 0.1001E+06 IMG DIS 0.0000 0.0000 0.0000 0.0000 OAL 150.0000 150.0000 150.0000 150.0000 PARAXIAL IMAGE HT 5.6849 5.7338 5.4578 5.3668 THI 0.0233 0.0301 0.0396 0.0008 ANG 38.2900 29.1031 19.3975 12.6055 ENTRANCE PUPIL DIA 2.4409 3.0746 4.0790 4.8482 THI 12.5423 11.5863 13.1371 14.3013 EXIT PUPIL DIA 168.7571 40.1336 24.9706 11.9870 THI 497.8567 −134.4174 −94.8486 −59.3348 STO DIA 9.4209 9.5872 9.1876 8.8816

FABRICATION DATA 28-Mar-09 CLZ6mmMockUpV030 ELEMENT RADIUS OF CURVATURE APERTURE DIAMETER NUMBER FRONT BACK THICKNESS FRONT BACK GLASS OBJECT INF 99999.0000 26.8424      5.0000  1 A(1)  −13.3109 CX   6.6220 17.6400 14.9480 883.407  2  −13.3109 CC   6.3729 CC   0.7000 14.9480  8.5776 661.306   4.3966  3  −5.4440 CC   −7.1210 CX   2.0149  6.9137  7.6800 883.407   0.1000  4  28.1372 CX  −15.2313 CX   5.5410  7.8203  9.1200 839.436   0.1000  5  14.5180 CX  −9.8347 CX   3.3324  9.3818  9.1017 738.492  6  −9.8347 CC −3968.8337 CX   7.0000  9.1017  8.9068 860.290   0.1000  7  42.7478 CX   9.1771 CC   0.7000  8.8393  8.5919 861.290   1.0956  8  79.2935 CX INF   0.8192  8.7009  8.9285 847.238  9 INF  −10.0000*4   4.6156  8.9285 10.6846 ‘OIL_C300’ 10  −10.0000*4 INF   8.1735 10.6846 15.3359 WATER 11 INF  −27.0930 CX   1.8534 15.3359 15.6451 847.238   12.0782 21.6617      0.7050 12  30.8939 CX  −30.4524 CX   7.1842 23.8150 23.6820 847.238   6.3077 13  33.5963 CX   0.1000E+19 CC   2.1897 14.0304 13.0349 435.950 14   0.1000E+19 CX   12.0000*5   2.0647*6 13.0349 11.4000 625.450 15  12.0000*5 INF   6.0000*7 11.4000 11.4000 WATER 16 INF   8.6379 CC   0.7000 11.4000 11.4000 847.238   0.9551 17  44.6671 CX  −18.9410 CX   1.3168  8.0530  8.0742 857.272 18  −18.9410 CC   96.1851 CC   0.7000  8.0742  7.9918 501.524 19  96.1851 CX   5.8357 CC   0.7000  7.9918  7.8448 645.380 20   5.8357 CX   16.4996 CC   1.7515  7.8448  7.7590 700.511   1.6816 21  50.5746 CX INF   0.8560  7.9400  7.9847 847.238 22 INF  −10.0392*2   1.5169  7.9847  8.0805 WATER 23  −10.0392*2 INF   5.4619  8.0805  8.8530 ‘OIL_C300’ 24 INF   27.1629 CC   4.7359  8.8530  9.5872 707.288 APERTURE STOP   9.5872     0.2899 25  30.4918 CX  −16.2562 CX   1.9272  9.9149 10.2057 806.463   0.1000 26  15.7630 CX   20.4791 CC   0.9403 10.6797 10.5468 850.427   1.9782 10.6766      0.0000 10.6766      0.0000 10.6766      12.4955 27  534.9639 CX  −24.3172 CX   1.4852 11.9400 12.0102 804.466   0.1000 28  25.1677 CX  −425.2385 CX   1.4208 11.6501 11.4115 804.465   0.9458 29  −19.5696 CC INF   0.7000 11.3126 11.2434 847.238 30 INF   7.2926*1   1.2858 11.2434 11.0056 WATER 31   7.2926*1 INF   3.8037 11.0056 10.6029 ‘OIL_C300’ 32 INF   8.9179 CC   0.7481 10.6029 10.0234 847.238   1.2261 33  27.9882 CX INF   1.1636 10.1504 10.3120 883.407 34 INF   15.8492*3   1.1160 10.3120 11.0034 WATER 35  15.8492*3 INF   9.1408 11.0034 12.5649 ‘OIL_C300’ 36 INF A(2)   2.3637 12.5649 12.7802 880.387   4.0000 11.0225      IMAGE DISTANCE =   0.0000 IMAGE INF 11.0225    NOTES Positive radius indicates the center of curvature is to the right Negative radius indicates the center of curvature is to the left Dimensions are given in millimeters Thickness is axial distance to next surface Image diameter shown above is a paraxial value, it is not a ray traced value Other glass suppliers can be used if their materials are functionally equivalent to the extent needed by the design; contact the designer for approval of substitutions.

ASPHERIC CONSTANTS $Z = {\frac{({CURV})Y^{2}}{1 + \left( {1 - {\left( {1 + K} \right)({CURV})^{2}Y^{2}}} \right)^{\frac{1}{2}}} + {(A)Y^{4}} + {(B)Y^{6}} + {(C)Y^{8}} + {(D)Y^{10}}}$ ASPHERIC CURV K A B C D A(1)  0.02974108 0.000000 −2.77553E−05 −2.67993E−07 −1.50270E−09 0.00000E+00 A(2) −0.03899025 0.000000 −6.58801E−05 −1.17390E−06  1.22063E−08 0.00000E+00 REFERENCE WAVELENGTH = 546.1 NM SPECTRAL REGION = 486.1-587.6 NM POS. 1 POS. 2 POS. 3 POS. 4 * ZOOM PARAMETERS *1 = 7.2926 8.0000 12.6595 −12.8591 *2 = −10.0392 −18.8155 −19.1180 42.7568 *3 = 15.8492 −34.9047 −25.0495 −19.0698 *4 = −10.0000 −62.9548 23.6475 10.5688 *5 = 12.0000 14.5000 −23.1476 −13.4106 *6 = 2.0647 4.0647 2.8629 1.8099 *7 = 6.0000 4.0000 5.2019 6.2548 INFINITE CONJUGATES EFL = −7.2007 −10.3000 −15.4998 −23.9964 BFL = 0.0228 0.0291 0.0372 −0.0049 FFL = 12.6465 10.7972 10.6052 4.5958 F/NO = −2.9500 −3.3500 −3.7999 −4.9495 AT USED CONJUGATES REDUCTION = −0.0001 −0.0001 −0.0002 −0.0002 FINITE F/NO = −2.9500 −3.3500 −3.8000 −4.9500 OBJECT DIST = 99999.0000 99999.0000 99999.0000 99999.0000 TOTAL TRACK = 100149.0000 100149.0000 100149.0000 100149.0000 IMAGE DIST = 0.0000 0.0000 0.0000 0.0000 OAL = 150.0000 150.0000 150.0000 150.0000 PARAXIAL IMAGE HT = 5.6849 5.7338 5.4578 5.3668 IMAGE DIST = 0.0233 0.0301 0.0396 0.0008 SEMI-FIELD ANGLE = 38.2900 29.1031 19.3975 12.6055 ENTR PUPIL DIAMETER = 2.4409 3.0746 4.0790 4.8482 DISTANCE = 12.5423 11.5863 13.1371 14.3013 EXIT PUPIL DIAMETER = 168.7571 40.1336 24.9706 11.9870 DISTANCE = 497.8567 −134.4174 −94.8486 −59.3348 APER STOP DIAMETER = 9.4209 9.5872 9.1876 8.8816 NOTES FFL is measured from the first surface BFL is measured from the last surface

APPENDIX 3 5 Cell - Stop in Objective CLZ6mmMockUpV030frtstpV03vig0 RDY  THI   RMD GLA CCY THC GLC > OBJ: INFINITY 99999.000000 100 100  1: INFINITY 5.000000 100 100  2: 28.48909 5.240433 883000.407000 100 100 100 ASP: K: 0.000000 KC: 100 IC: YES CUF: 0.000000 CCF: 100 A: −.312775E−04 B: −.301860E−06 C: −.190512E−09 D: 0.000000E+00 AC: 100 BC: 100 CC: 100 DC: 100  3: −16.98464 0.700000 656753.335912 100 100 100  4: 6.15698 4.818655 100 100  5: −5.23300 1.934885 883000.407000 100 100 100 STO: −6.73596 0.100000 100 100  7: 25.65070 5.024826 838504.436872 100 100 100  8: −14.63176 0.209327 100 100  9: 17.43232 3.188598 729107.496639 100 100 100 10: −8.89070 0.733060 860622.283739 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 11: 105.77410 0.108963 100 100 12: 31.54862 0.725067 852449.254572 100 100 100 13: 9.79470 1.084430 100 100 14: 80.65186 0.795202 847000.238000 100 100 100 15: INFINITY 4.623189 ‘OIL_C300’ 100 100 16: −10.00000 9.059530 WATER_SPECIAL 100 100 17: INFINITY 1.983652 847000.238000 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 18: −27.69469 12.843004 100 100 19: INFINITY 0.704953 100 100 20: 30.57771 6.632709 853139.256823 100 100 100 21: −33.45675 4.821003 100 100 22: 30.31291 2.337867 435000.950000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 23: INFINITY 2.119096 625000.4500000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 24: 12.00000 6.000000 WATER_SPECIAL 100 100 25: INFINITY 0.700000 842594.244222 100 100 100 26: 10.11602 1.177672 100 100 27: 694.87494 1.413217 860539.283416 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 28: −14.89419 0.700000 556685.405227 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 29: −46.05553 0.700000 640527.339362 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 30: 7.13975 1.800732 724875.498694 100 100 100 31: 17.34247 1.842634 100 100 32: 43.62234 0.996475 847000.238000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 33: INFINITY 1.973800 WATER_SPECIAL 100 100 34: −9.61212 4.816388 ‘OIL_C300’ 100 100 35: INFINITY 3.990571 707651.331396 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 36: 26.18141 0.235574 100 100 37: 29.42292 3.023260 804333.465688 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 38: −19.01622 0.100000 100 100 39: 17.30787 1.295256 842278.434040 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 40: 26.77671 1.978245 100 100 41: INFINITY 0.000000 100 100 42: INFINITY 0.000000 100 100 43: INFINITY 12.499989 100 100 44: −454.97977 1.433083 806049.464089 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 45: −21.57609 0.100000 100 100 46: 26.92021 1.366079 846118.431220 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 47: −228.71741 0.889186 100 100 48: −19.53544 0.700000 836621.240360 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 49: INFINITY 1.332006 WATER_SPECIAL 100 100 50: 7.30941 3.631821 ‘OIL_C300’ 100 100 51: INFINITY 1.095823 817211.245069 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 52: 8.84686 1.077835 100 100 53: 22.83742 1.241882 883000.407000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 54: INFINITY 1.117228 WATER_SPECIAL 100 100 55: 28.16710 9.806000 ‘OIL_C300’ 100 100 56: INFINITY 2.158092 883000.407000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 57: −31.46496 4.018705 100 100   ASP: K: 0.000000 KC: 100 IC: YES CUF: 0.000000 CCF: 100 A: −.786715E−04 B: −.101753E−05 C: 0.852094E−08 D: 0.000000E+00 AC: 100 BC: 100 CC: 100 DC: 100 58: INFINITY 0.000000 100 100 IMG: INFINITY 0.000000 100 100

SPECIFICATION DATA FNO 2.95000 DIM MM WL 587.56 546.07 486.13 REF 2 WTW 88  99   77  INI IAN XRI 0.00000 0.00000 0.00000 0.00000 0.00000  YRI 0.00000 2.20000 3.57500 4.67500 5.50000  WTF 1.00000 1.00000 1.00000 1.00000 1.00000  VUY 0.00000 0.00000 0.00000 0.00000 0.00000  VLY 0.00000 0.00000 0.00000 0.00000 0.00000  POL    N   APERTURE DATA/EDGE DEFINITIONS CA APE APERTURE data not specified for surface Obj thru 59 PRIVATE CATALOG PWL 656.30 589.30 546.10 486.00 ‘OIL_C300’  1.511500  1.515000  1.518000  1.523800 REFRACTIVE INDICES GLASS CODE 587.56 546.07 486.13 WATER_SPECIAL  1.333041  1.334468  1.337129 ‘OIL_C300’  1.515107  1.518002  1.523784 860539.283416  1.860539  1.867712  1.882124 847000.238000  1.847000  1.855385  1.872415 707651.331396  1.707651  1.712706  1.722770 804333.465688  1.804333  1.808439  1.816450 842278.434040  1.842278  1.846887  1.855920 806049.464089  1.806049  1.810177  1.818234 846118.431220  1.846118  1.850778  1.859915 836621.240360  1.836621  1.844824  1.861472 817211.245069  1.817211  1.825071  1.841006 883000.407000  1.883000  1.888148  1.898279 883000.407000  1.883000  1.888148  1.898279 860622.283739  1.860622  1.867787  1.882183 847000.238000  1.847000  1.855385  1.872415 656753.335912  1.656753  1.661382  1.670592 724875.498694  1.724875  1.728333  1.735049 883000.407000  1.883000  1.888148  1.898279 883000.407000  1.883000  1.888148  1.898279 838504.436872  1.838504  1.843063  1.851994 729107.496639  1.729107  1.732600  1.739384 852449.254572  1.852449  1.860347  1.876319 847000.238000  1.847000  1.855385  1.872415 853139.256823  1.853139  1.860976  1.876814 842594.244222  1.842594  1.850727  1.867216 435000.950000  1.435000  1.436102  1.438080 556685.405227  1.556685  1.559945  1.566361 640527.339362  1.640527  1.644996  1.653882 625000.450000  1.625000  1.628300  1.634754 No solves defined in system No pickups defined in system

POS 1 POS 2 POS 3 POS 4 ZOOM DATA FNO 2.95000 3.35000 3.80000 4.95000 VUY F1 0.00000 0.00000 0.00000 0.00000 VLY F1 0.00000 0.00000 0.00000 0.00000 VUY F2 0.00000 0.00000 0.00000 0.00000 VLY F2 0.00000 0.00000 0.00000 0.00000 VUY F3 0.00000 0.00000 0.00000 0.00000 VLY F3 0.00000 0.00000 0.00000 0.00000 VUY F4 0.00000 0.00000 0.00000 0.00000 VLY F4 0.00000 0.00000 0.00000 0.00000 VUY F5 0.00000 0.00000 0.00000 0.00000 VLY F5 0.00000 0.00000 0.00000 0.00000 VUX F1 0.00000 0.00000 0.00000 0.00000 VLX F1 0.00000 0.00000 0.00000 0.00000 VUX F2 0.00000 0.00000 0.00000 0.00000 VLX F2 0.00000 0.00000 0.00000 0.00000 VUX F3 0.00000 0.00000 0.00000 0.00000 VLX F3 0.00000 0.00000 0.00000 0.00000 VUX F4 0.00000 0.00000 0.00000 0.00000 VLX F4 0.00000 0.00000 0.00000 0.00000 VUX F5 0.00000 0.00000 0.00000 0.00000 VLX F5 0.00000 0.00000 0.00000 0.00000 RSL DEF DEF DEF DEF RDY S16 −10.00000 −155.66275 27.96590 11.40863 CCY S16 100 100 100 100 THI S23 2.11910 4.11910 2.66822 1.72660 THC S23 100 100 100 100 RDY S24 12.00000 14.50000 −28.97862 −14.25091 CCY S24 100 100 100 100 THI S24 6.00000 4.00000 5.45088 6.39250 THC S24 100 100 100 100 RDY S34 −9.61212 −17.20793 −25.37979 28.03944 CCY S34 100 100 100 100 RDY S50 7.30941 8.00000 15.21459 −12.81797 CCY S50 100 100 100 100 RDY S55 28.16710 −32.97451 −24.97175 −20.00000 CCY S55 100 100 100 100   INFINITE CONJUGATES EFL −7.2005 −10.2999 −15.4999 −23.9985 BFL 0.0196 0.0092 0.0221 −0.0090 FFL 11.1264 9.0132 8.8455 2.5130 FNO −2.9499 −3.3498 −3.7998 −4.9494 AT USED CONJUGATES RED −0.0001 −0.0001 −0.0002 −0.0002 FNO −2.9500 −3.3500 −3.8000 −4.9500 OBJ DIS 99999.0000 99999.0000 99999.0000 99999.0000 TT 0.1001E+06 0.1001E+06 0.1001E+06 0.1001E+06 IMG DIS 0.0000 0.0000 0.0000 0.0000 OAL 150.0000 150.0000 150.0000 150.0000 PARAXIAL IMAGE HT 5.7022 5.7284 5.4484 5.3671 THI 0.0201 0.0103 0.0245 −0.0032 ANG 38.3756 29.0797 19.3663 12.6050 ENTRANCE PUPIL DIA 2.4409 3.0748 4.0791 4.8487 THI 13.8710 13.8710 13.8710 13.8710 EXIT PUPIL DIA 6.4038 6.5194 12.5811 10.2450 THI −18.8712 −21.8298 −47.7837 −50.7162 STO DIA 3.4072 4.2771 5.6309 6.6396

FABRICATION DATA 28-Mar-09 CLZ6mmMockUpV030frtstpV03vig0 ELEMENT RADIUS OF CURVATURE APERTURE DIAMETER NUMBER FRONT BACK THICKNESS FRONT BACK GLASS OBJECT INF 99999.0000 23.5650      5.0000  1 A(1)  −16.9846 CX   5.2404 14.3854 11.1782 883.407  2  −16.9846 CC   6.1570 CC   0.7000 11.1782  7.4518 656.335   4.8187  3  −5.2330 CC  −6.7360 CX   1.9349  5.7808  6.6396 883.407 APERTURE STOP   6.6396     0.1000  4  25.6507 CX  −14.6318 CX   5.0248  7.2688  8.1307 838.436   0.2093  5  17.4323 CX  −8.8907 CX   3.1886  7.9983  7.5083 729.496  6  −8.8907 CC  105.7741 CX   0.7331  7.5083  7.2359 860.283   0.1090  7  31.5486 CX   9.7947 CC   0.7251  7.1720  7.2537 852.254   1.0844  8  80.6519 CX INF   0.7952  7.8351  8.2016 847.238  9 INF  −10.0000*4   4.6232  8.2016 10.2843 ‘OIL_C300’ 10  −10.0000*4 INF   9.0595 10.2843 16.3805 WATER 11 INF  −27.6947 CX   1.9837 16.3805 16.6675 847.238   12.8430 21.5262      0.7050 12  30.5777 CX  −33.4567 CX   6.6327 23.0124 22.7116 853.256   4.8210 13  30.3129 CX   0.1000E+19 CC   2.3379 14.6342 13.7211 435.950 14   0.1000E+19 CX  12.0000*5   2.1191*6 13.7211 11.0000 625.450 15  12.0000*5 INF   6.0000*7 11.0000  9.3945 WATER 16 INF  10.1160 CC   0.7000  9.3945  8.8398 842.244   1.1777 17  694.8749 CX  −14.8942 CX   1.4132  8.8984  9.0184 860.283 18  −14.8942 CC  −46.0555 CX   0.7000  9.0184  9.1138 556.405 19  −46.0555 CC   7.1398 CC   0.7000  9.1138  9.3472 640.339 20   7.1398 CX  17.3425 CC   1.8007  9.3472  9.3458 724.498   1.8426 21  43.6223 CX INF   0.9965 10.1544 10.2896 847.238 22 INF  −9.6121*2   1.9738 10.2896 10.5964 WATER 23  −9.6121*2 INF   4.8164 10.5964 12.3727 ‘OIL_C300’ 24 INF  26.1814 CC   3.9906 12.3727 13.7359 707.331   0.2356 25  29.4229 CX  −19.0162 CX   3.0233 13.8890 14.1084 804.465   0.1000 26  17.3079 CX  26.7767 CC   1.2953 13.6346 13.2871 842.434   1.9782 12.8964      0.0000 12.8964      0.0000 12.8964      12.5000 27 −454.9798 CC  −21.5761 CX   1.4331 11.3029 11.4120 806.464   0.1000 28  26.9202 CX −228.7174 CX   1.3661 11.1759 10.9746 846.431   0.8892 29  −19.5354 CC INF   0.7000 10.8675 10.8306 836.240 30 INF   7.3094*1   1.3320 10.8306 10.7036 WATER 31   7.3094*1 INF   3.6318 10.7036 10.3480 ‘OIL_C300’ 32 INF   8.8469 CC   1.0958 10.3480  9.7662 817.245   1.0778 33  22.8374 CX INF   1.2419  9.8908 10.0182 883.407 34 INF  28.1671*3   1.1172 10.0182 10.4333 WATER 35  28.1671*3 INF   9.8060 10.4333 12.1058 ‘OIL_C300’ 36 INF A(2)   2.1581 12.1058 12.3076 883.407   4.0187 11.0141      IMAGE DISTANCE =   0.0000 IMAGE INF 11.0141    NOTES Positive radius indicates the center of curvature is to the right Negative radius indicates the center of curvature is to the left Dimensions are given in millimeters Thickness is axial distance to next surface Image diameter shown above is a paraxial value, it is not a ray traced value Other glass suppliers can be used if their materials are functionally equivalent to the extent needed by the design; contact the designer for approval of substitutions.

ASPHERIC CONSTANTS $Z = {\frac{({CURV})Y^{2}}{1 + \left( {1 - {\left( {1 + K} \right)({CURV})^{2}Y^{2}}} \right)^{\frac{1}{2}}} + {(A)Y^{4}} + {(B)Y^{6}} + {(C)Y^{8}} + {(D)Y^{10}}}$ ASPHERIC CURV K A B C D A(1)  0.03510115 0.000000 −3.12775E−05 −3.01860E−07 −1.90512E−10 0.00000E+00 A(2) −0.03178139 0.000000 −7.86715E−05 −1.01753E−06  8.52094E−09 0.00000E+00 REFERENCE WAVELENGTH = 546.1 NM SPECTRAL REGION = 486.1-587.6 NM POS. 1 POS. 2 POS. 3 POS. 4 * ZOOM PARAMETERS *1 = 7.3094 8.0000 15.2146 −12.8180 *2 = −9.6121 −17.2079 −25.3798 28.0394 *3 = 28.1671 −32.9745 −24.9717 −20.0000 *4 = −10.0000 −155.6628 27.9659 11.4086 *5 = 12.0000 14.5000 −28.9786 −14.2509 *6 = 2.1191 4.1191 2.6682 1.7266 *7 = 6.0000 4.0000 5.4509 6.3925 INFINITE CONJUGATES EFL = −7.2005 −10.2999 −15.4999 −23.9985 BFL = 0.0196 0.0092 0.0221 −0.0090 FFL = 11.1264 9.0132 8.8455 2.5130 F/NO = −2.9499 −3.3498 −3.7998 −4.9494 AT USED CONJUGATES REDUCTION = −0.0001 −0.0001 −0.0002 −0.0002 FINITE F/NO = −2.9500 −3.3500 −3.8000 −4.9500 OBJECT DIST = 99999.0000 99999.0000 99999.0000 99999.0000 TOTAL TRACK = 100149.0000 100149.0000 100149.0000 100149.0000 IMAGE DIST = 0.0000 0.0000 0.0000 0.0000 OAL = 150.0000 150.0000 150.0000 150.0000 PARAXIAL IMAGE HT = 5.7022 5.7284 5.4484 5.3671 IMAGE DIST = 0.0201 0.0103 0.0245 −0.0032 SEMI-FIELD ANGLE = 38.3756 29.0797 19.3663 12.6050 ENTR PUPIL DIAMETER = 2.4409 3.0748 4.0791 4.8487 DISTANCE = 13.8710 13.8710 13.8710 13.8710 EXIT PUPIL DIAMETER = 6.4038 6.5194 12.5811 10.2450 DISTANCE = −18.8712 −21.8298 −47.7837 −50.7162 APER STOP DIAMETER = 3.4072 4.2771 5.6309 6.6396 NOTES FFL is measured from the first surface BFL is measured from the last surface

APPENDIX 4 4 Cell - Stop in Relay CLZ6mmMockUpV040T3 RDY  THI   RMD GLA CCY THC GLC > OBJ: INFINITY 99999.000000 100 100  1: INFINITY 5.000000 100 100  2: 34.96693 7.582251   783905.473287 100 100 100 ASP: K: 0.000000 KC: 100 IC: YES CUF: 0.000000 CCF: 100 A: −.526263E−04 B: 0.991916E−07 C: −.127079E−09 D: 0.000000E+00 AC: 100 BC: 100 CC: 100 DC: 100  3: −24.08847 0.936487 511629.494504 100 100 100  4: 7.41471 6.074420 100 100  5: −7.49021 0.700000 746107.266519 100 100 100  6: −9.38558 0.100030 100 100  7: 23.56860 1.457626 846999.238000 100 100 100  8: −43.02689 2.027224 100 100  9: 31.36513 1.621869 804000.466000 100 100 100 10: −6.56828 0.700000 827547.283525 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 11: −25.51682 0.978217 100 100 12: 13.92228 0.700000 718097.277404 100 100 100 13: 7.87616 1.693147 100 100 14: 132.86406 0.758236 883000.407000 100 100 100 15: INFINITY 5.513185 ‘OIL_C300’ 100 100 16: −7.20069 3.950252 WATER_SPECIAL 100 100 17: INFINITY 1.565435 847002.238005 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 18: −30.30783 12.147162 100 100 19: INFINITY 0.704953 100 100 20: 24.87008 7.722846 856799.287722 100 100 100 21: −52.19502 14.073019 100 100 22: 36.71570 1.972177 472088.806494 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 23: INFINITY 1.000000 624999.475001 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 24: 9.24690 4.799896 WATER_SPECIAL 100 100 25: INFINITY 0.700000 847000.238001 100 100 100 26: 11.97646 0.819028 100 100 27: 33.15844 2.704275 883000.406998 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 28: −8.03712 2.235217 708586.281522 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 29: −23.46355 3.591664 100 100 30: −8.05010 0.743220 784408.259752 100 100 100 31: 23.99115 2.288480 100 100 32: −50.37935 0.970763 846999.238009 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 33: −21.79495 1.245580 WATER_SPECIAL 100 100 34: −11.07591 0.926021 856694.317013 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 35: −10.17631 0.705078 601542.351496 100 100 100 GP1: SBSL7_OHARA SPG: PRC: STO: −248.22685 0.100000 100 100 37: −542.93020 2.266884 821590.450376 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 38: −10.81592 0.100934 100 100 39: 28.11385 1.239058 868221.316909 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 40: 201.30177 1.978245 100 100 41: INFINITY 0.000000 100 100 42: INFINITY 0.000000 100 100 43: INFINITY 12.497311 100 100 44: −11.77330 1.492556 436889.926054 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 45: −10.59700 0.100000 100 100 46: 26.16072 2.256137 768949.479117 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 47: −18.00228 0.360955 100 100 48: −14.47989 0.700000 847000.238000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 49: INFINITY 0.700000 WATER_SPECIAL 100 100 50: 6.36080 4.454749 ‘OIL_C300’ 100 100 51: INFINITY 0.700000 847000.238000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 52: 7.49895 1.179851 100 100 53: 16.74607 1.446621 804000.466000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 54: INFINITY 1.109231 WATER_SPECIAL 100 100 55: 12.74082 9.945742 ‘OIL_C300’ 100 100 56: INFINITY 2.663776 483754.773570 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 57: −106.52095 4.000000 100 100 ASP: K: 0.000000 KC: 100 IC: YES CUF: 0.000000 CCF: 100 A: −.303962E−03 B: −.122247E−04 C: 0.138536E−06 D: 0.000000E+00 AC: 100 BC: 100 CC: 100 DC: 100 58: INFINITY 0.000000 100 100 IMG: INFINITY 0.000000 100 100

SPECIFICATION DATA FNO 2.95000 DIM MM WL 587.56 546.07 486.13 REF 2 WTW 88  99   77  INI IAN XRI 0.00000 0.00000 0.00000 0.00000 0.00000  YRI 0.00000 2.20000 3.57500 4.67500 5.50000  WTF 1.00000 1.00000 1.00000 1.00000 1.00000  VUX 0.00000 −0.02268 −0.08258 −0.18153 0.03337  VLX 0.00000 −0.02268 −0.08258 −0.18153 0.03337  VUY 0.00000 −0.09827 −0.37073 −0.90283 0.60862  VLY 0.00000 −0.06411 0.09219 −0.53512 −1.17789  POL   N APERTURE DATA/EDGE DEFINITIONS CA APE CIR S2 12.800000 CIR S6 5.600000 CIR S11 2.610000 CIR S24 5.500000 CIR S25 5.500000 CIR S26 5.500000 CIR S32 4.240000 CIR S44 5.500000 PRIVATE CATALOG PWL 656.30 589.30 546.10 486.00 ‘OIL_C300’  1.511500  1.515000  1.518000  1.523800 REFRACTIVE INDICES GLASS CODE 587.56 546.07 486.13 WATER_SPECIAL  1.333041  1.334468  1.337129 ‘OIL_C300’  1.515107  1.518002  1.523784 883000.406998  1.883000  1.888148  1.898279 846999.238009  1.846999  1.855384  1.872413 601542.351496  1.601542  1.605596  1.613641 821590.450376  1.821590  1.825925  1.834401 868221.316909  1.868221  1.874702  1.887641 436889.926054  1.436889  1.438022  1.440072 768949.479117  1.768949  1.772765  1.780198 847000.238000  1.847000  1.855385  1.872415 847000.238000  1.847000  1.855385  1.872415 804000.466000  1.804000  1.808102  1.816104 483754.773570  1.483754  1.485247  1.488038 827547.283525  1.827547  1.834443  1.848296 847002.238005  1.847002  1.855387  1.872416 511629.494504  1.511629  1.514090  1.518873 784408.259752  1.784408  1.791533  1.805924 783905.473287  1.783905  1.787843  1.795518 746107.266519  1.746107  1.752715  1.766039 846999.238000  1.846999  1.855384  1.872414 804000.466000  1.804000  1.808101  1.816103 718097.277404  1.718097  1.724211  1.736509 883000.407000  1.883000  1.888148  1.898279 856799.287722  1.856799  1.863835  1.877959 847000.238001  1.847000  1.855385  1.872415 472088.806494  1.472088  1.473486  1.476086 708586.281522  1.708586  1.714531  1.726481 624999.475001  1.624999  1.628128  1.634224 856694.317013    1.856694  1.863088  1.875850 No solves defined in system No pickups defined in system

POS 1 POS 2 POS 3 POS 4 ZOOM DATA FNO 2.95000 3.35000 3.80000 4.95000 VUY F1 −0.3725E−09 −0.3725E−09 −0.3725E−09 −0.3725E−09 VLY F1 −0.3725E−09 −0.3725E−09 −0.3725E−09 −0.3725E−09 VUY F2 −0.09827 −0.06248 −0.03468 −0.04542 VLY F2 −0.06411 0.10522 0.14242 0.19846 VUY F3 −0.37073 −0.19068 −0.08898 −0.11797 VLY F3 0.09219 0.39567 0.31861 0.30004 VUY F4 −0.90283 −0.39973 −0.15147 −0.21248 VLY F4 −0.53512 0.36548 0.40965 0.34965 VUY F5 0.60862 −0.64221 −0.23027 −0.29146 VLY F5 −1.17789 −0.08041 0.41695 0.34991 VUX F1 −0.3725E−09 −0.3725E−09 −0.3725E−09 −0.3725E−09 VLX F1 −0.3725E−09 −0.3725E−09 −0.3725E−09 −0.3725E−09 VUX F2 −0.02268 −0.01653 −0.00864 0.02038 VLX F2 −0.02268 −0.01653 −0.00864 0.02038 VUX F3 −0.08258 −0.05011 −0.02444 0.04722 VLX F3 −0.08258 −0.05011 −0.02444 0.04722 VUX F4 −0.18153 −0.09973 −0.02760 0.06457 VLX F4 −0.18153 −0.09973 −0.02760 0.06457 VUX F5 0.03337 −0.15623 −0.02297 0.06533 VLX F5 0.03337 −0.15623 −0.02297 0.06533 RSL DEF DEF DEF DEF RDY S16 −7.20069 −39.07764 153.94838 7.07041 CCY S16 100 100 100 100 THI S23 1.00000 4.23534 4.99810 2.37206 THC S23 100 100 100 100 RDY S24 9.24690 18.79816 −37.25252 −11.09884 CCY S24 100 100 100 100 THI S24 4.79990 1.56455 0.80178 3.42780 THC S24 100 100 100 100 RDY S50 6.36080 6.37458 8.31340 10.89980 CCY S50 100 100 100 100 RDY S55 12.74082 24.00288 −24.90664 −17.55066 CCY S55 100 100 100 100   INFINITE CONJUGATES EFL −7.2000 −10.2999 −15.4990 −23.9965 BFL 0.0005 0.0408 −0.0183 −0.0178 FFL 15.6068 12.6169 7.8656 −4.4621 FNO −2.9500 −3.3499 −3.7997 −4.9490 AT USED CONJUGATES RED −0.0001 −0.0001 −0.0002 −0.0002 FNO −2.9500 −3.3500 −3.8000 −4.9500 OBJ DIS 99999.0000 99999.0000 99999.0000 99999.0000 TT 0.1001E+06 0.1001E+06 0.1001E+06 0.1001E+06 IMG DIS 0.0000 0.0000 0.0000 0.0000 OAL 149.9998 149.9998 149.9998 149.9998 PARAXIAL IMAGE HT 5.7222 5.7247 5.6980 5.3715 THI 0.0010 0.0418 −0.0159 −0.0121 ANG 38.4742 29.0640 20.1838 12.6149 ENTRANCE PUPIL DIA 2.4407 3.0747 4.0790 4.8487 THI 16.6903 15.1724 15.4390 14.8225 EXIT PUPIL DIA 16.2189 12.3924 8.3477 6.0334 THI −47.8448 −41.4726 −31.7371 −29.8775 STO DIA 10.6911 9.8503 10.5149 8.4464

FABRICATION DATA 28-Mar-09 CLZ6mmMockUpV040T3 ELEMENT RADIUS OF CURVATURE APERTURE DIAMETER NUMBER FRONT BACK THICKNESS FRONT BACK GLASS OBJECT INF 99999.0000 35.4164    5.0000  1 A(1)  −24.0885 CX   7.5823 25.6000 22.3050 783.473  2  −24.0885 CC   7.4147 CC   0.9365 22.3050 11.7251 511.494   6.0744  3  −7.4902 CC  −9.3856 CX   7.0000 10.2988 11.2000 746.266   0.1000  4  23.5686 CX  −43.0269 CX   1.4576  9.6739  9.3714 846.238   2.0272  5  31.3651 CX  −6.5683 CX   1.6219  6.5711  6.0932 804.466  6  −6.5683 CC  −25.5168 CX   0.7000  6.0932  5.2200 827.283   0.9782  7  13.9223 CX   7.8762 CC   0.7000  6.3252  6.5023 718.277   1.6931  8  132.8641 CX INF   0.7582  7.8667  8.2647 883.407  9 INF  −7.2007*3   5.5132  8.2647 10.5781 ‘OIL_C300’ 10  −7.2007*3 INF   3.9503 10.5781 14.1038 WATER 11 INF  −30.3078 CX   1.5654 14.1038 14.3819 847.238   12.1472 22.1075    0.7050 12  24.8701 CX  −52.1950 CX   7.7228 26.1493 25.7189 856.287   14.0730 13  36.7157 CX   0.1000E+19 CC   1.9722 13.2822 12.6368 472.806 14   0.1000E+19 CX   9.2469*4   1.0000*5 12.6368 11.0000 624.475 15   9.2469*4 INF   4.7999*6 11.0000 11.0000 WATER 16 INF  11.9765 CC   0.7000 11.0000 11.0000 847.238   0.8190 17  33.1584 CX  −8.0371 CX   2.7043  9.7515  9.7407 883.406 18  −8.0371 CC  −23.4636 CX   2.2352  9.7407  9.1309 708.281   3.5917 19  −8.0501 CC  23.9912 CC   0.7432  7.1752  7.4588 784.259   2.2885 20  −50.3794 CC  −21.7950 CX   0.9708  8.4800  8.8012 846.238 21  −21.7950 CC  −11.0759 CX   1.2456  8.8012  9.1684 WATER 22  −11.0759 CC  −10.1763 CX   0.9260  9.1684  9.6243 856.317 23  −10.1763 CC −248.2269 CX   0.7051  9.6243 10.6911 601.351 APERTURE STOP   10.6911    0.1000 24 −542.9302 CC  −10.8159 CX   2.2669 10.8529 11.3031 821.450   0.1009 25  28.1138 CX  201.3018 CC   1.2391 11.7843 11.7208 868.316   1.9782 11.4950    0.0000 11.4950    0.0000 11.4950    12.4973   26  −11.7733 CC  −10.5970 CX   1.4926 11.0000 11.3191 436.926   0.1000 27  26.1607 CX  −18.0023 CX   2.2561 11.4702 11.3586 768.479   0.3610 28  −14.4799 CC INF   0.7000 11.2166 11.1613 847.238 29 INF   6.3608*1   0.7000 11.1613 10.9988 WATER 30   6.3608*1 INF   4.4547 10.9988 10.4881 ‘OIL_C300’ 31 INF   7.4990 CC   0.7000 10.4881  9.6916 847.238   1.1799 32  16.7461 CX INF   1.4466  9.8889 10.0872 804.466 33 INF  12.7408*2   1.1092 10.0872 10.9994 WATER 34  12.7408*2 INF   9.9457 10.9994 12.8196 ‘OIL_C300’ 35 INF A(2)   2.6638 12.8196 13.1191 483.773   4.0000 11.0089  IMAGE DISTANCE =   0.0000 IMAGE INF 11.0089  NOTES Positive radius indicates the center of curvature is to the right Negative radius indicates the center of curvature is to the left Dimensions are given in millimeters Thickness is axial distance to next surface Image diameter shown above is a paraxial value, it is not a ray traced value Other glass suppliers can be used if their materials are functionally equivalent to the extent needed by the design; contact the designer for approval of substitutions.

ASPHERIC CONSTANTS $Z = {\frac{({CURV})Y^{2}}{1 + \left( {1 - {\left( {1 + K} \right)({CURV})^{2}Y^{2}}} \right)^{\frac{1}{2}}} + {(A)Y^{4}} + {(B)Y^{6}} + {(C)Y^{8}} + {(D)Y^{10}}}$ ASPHERIC CURV K A B C D A(1)  0.02859845 0.000000 −5.26263E−05  9.91916E−08 −1.27079E−10 0.00000E+00 A(2) −0.00938782 0.000000 −3.03962E−04 −1.22247E−05  1.38536E−07 0.00000E+00 REFERENCE WAVELENGTH = 546.1 NM SPECTRAL REGION = 486.1-587.6 NM POS. 1 POS. 2 POS. 3 POS. 4 * ZOOM PARAMETERS *1 = 6.3608 6.3746 8.3134 10.8998 *2 = 12.7408 24.0029 −24.9066 −17.5507 *3 = −7.2007 −39.0776 153.9484 7.0704 *4 = 9.2469 18.7982 −37.2525 −11.0988 *5 = 1.0000 4.2353 4.9981 2.3721 *6 = 4.7999 1.5645 0.8018 3.4278 INFINITE CONJUGATES EFL = −7.2000 −10.2999 −15.4990 −23.9965 BFL = 0.0005 0.0408 −0.0183 −0.0178 FFL = 15.6068 12.6169 7.8656 −4.4621 F/NO = −2.9500 −3.3499 −3.7997 −4.9490 AT USED CONJUGATES REDUCTION = −0.0001 −0.0001 −0.0002 −0.0002 FINITE F/NO = −2.9500 −3.3500 −3.8000 −4.9500 OBJECT DIST = 99999.0000 99999.0000 99999.0000 99999.0000 TOTAL TRACK = 100148.9998 100148.9998 100148.9998 100148.9998 IMAGE DIST = 0.0000 0.0000 0.0000 0.0000 OAL = 149.9998 149.9998 149.9998 149.9998 PARAXIAL IMAGE HT = 5.7222 5.7247 5.6980 5.3715 IMAGE DIST = 0.0010 0.0418 −0.0159 −0.0121 SEMI-FIELD ANGLE = 38.4742 29.0640 20.1838 12.6149 ENTR PUPIL DIAMETER = 2.4407 3.0747 4.0790 4.8487 DISTANCE = 16.6903 15.1724 15.4390 14.8225 EXIT PUPIL DIAMETER = 16.2189 12.3924 8.3477 6.0334 DISTANCE = −47.8448 −41.4726 −31.7371 −29.8775 APER STOP DIAMETER = 10.6911 9.8503 10.5149 8.4464 NOTES FFL is measured from the first surface BFL is measured from the last surface

APPENDIX 5 3 Cell - Stop in Relay CLZ6mmMockUpV050T1 RDY  THI   RMD GLA CCY THC GLC > OBJ: INFINITY 99999.000000 100 100  1: INFINITY 5.000000 100 100  2: 22.98496 9.038350 883000.407000 100 100 100 ASP: K: 0.000000 KC: 100 IC: YES CUF: 0.000000 CCF: 100 A: −.352307E−04 B: 0.326666E−08 C: −.106122E−09 D: 0.000000E+00 AC: 100 BC: 100 CC: 100 DC: 100  3: −27.99530 2.406854 606913.346451 100 100 100  4: 5.80564 3.905180 100 100  5: −8.12926 0.700000 847000.238000 100 100 100  6: −9.29806 0.099932 100 100  7: 45.59253 1.183978 883000.407000 100 100 100  8: −21.79978 4.220067 100 100  9: −4.75409 1.264918 883000.407000 100 100 100 10: −8.77179 0.700000 710425.287412 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 11: −13.05595 0.100000 100 100 12: 26.66068 0.700000 816295.245301 100 100 100 13: 11.54140 0.666499 100 100 14: 35.28876 0.962344 883000.407000 100 100 100 15: INFINITY 4.604297 720856.500684 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 16: −11.43113 3.704912 WATER_SPECIAL 100 100 17: INFINITY 1.629176 874782.351787 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 18: −29.83410 12.097030 100 100 19: INFINITY 0.704953 100 100 20: 32.42217 6.355986 862411.292604 100 100 100 21: −36.12265 9.266355 100 100 22: 23.59824 2.557805 831568.442245 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 23: INFINITY 2.677895 625000.475000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 24: 8.85890 3.818587 WATER_SPECIAL 100 100 25: INFINITY 0.699997 847000.238000 100 100 100 26: 12.90867 0.992774 100 100 27: 93.01541 2.608957 831850.442022 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 28: −7.52064 7.638843 847000.238000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 29: −15.02388 2.371407 100 100 30: −7.01723 0.700000 801337.249239 100 100 100 31: 30.46619 2.002889 100 100 32: −29.18742 0.920133 826663.446181 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 33: −19.90347 1.191723 WATER_SPECIAL 100 100 34: −11.34791 1.282651 883000.407000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 35: −8.38031 0.702874 619352.335615 100 100 100 GP1: SBSL7_OHARA SPG: PRC: STO: 162.49702 0.141605 100 100 37: 127.10319 2.574684 804000.466000 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 38: −10.83901 0.100000 100 100 39: 24.63411 1.332523 847000.238000 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 40: 281.82598 1.978245 100 100 41: INFINITY 0.000000 100 100 42: INFINITY 0.000000 100 100 43: INFINITY 12.501080 100 100 44: −13.54810 5.646859 883000.407000 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 45: −15.67021 0.113120 100 100 46: 24.65559 2.547500 743005.490167 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 47: −16.51236 0.192064 100 100 48: −15.66852 0.700000 847000.238000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 49: 69.91802 0.700000 WATER_SPECIAL 100 100 50: 7.18240 4.218720 ‘OIL_C300’ 100 100 51: −19.73544 0.700000 847000.238000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 52: 11.44881 0.713844 100 100 53: 19.85210 1.436246 810665.459949 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 54: INFINITY 0.696719 WATER_SPECIAL 100 100 55: 14.53352 9.529426 ‘OIL_C300’ 100 100 56: INFINITY 0.700000 SFPL33_OHARA 100 100 57: 67.30694 4.000000 100 100 ASP: K: 0.000000 KC: 100 IC: YES CUF: 0.000000 CCF: 100 A: −.835273E−04 B: −.232025E−05 C: 0.405318E−07 D: 0.000000E+00 AC: 100 BC: 100 CC: 100 DC: 100 58: INFINITY 0.000000 100 100 IMG: INFINITY 0.000000 100 100 SPECIFICATION DATA FNO 2.95000 DIM MM WL 587.56 546.07 486.13 REF 2 WTW 88  99    77   INI IAN XRI 0.00000 0.00000 0.00000 0.00000 0.00000 YRI 0.00000 2.20000 3.57500 4.67500 5.50000 WTF 1.00000 1.00000 1.00000 1.00000 1.00000 VUX 0.00000 −0.02268 −0.08258 −0.18153 0.03337 VLX 0.00000 −0.02268 −0.08258 −0.18153 0.03337 VUY 0.00000 −0.09827 −0.37073 −0.90283 0.60862 VLY 0.00000 −0.06411 0.09219 −0.53512 −1.17789 POL N APERTURE DATA/EDGE DEFINITIONS CA APE CIR S2  13.965848 CIR S6  5.600000 CIR S11  2.610000 CIR S24  5.500000 CIR S25  5.500000 CIR S26  5.500000 CIR S32  4.240000 CIR S44  5.500000 PRIVATE CATALOG PWL 656.30 589.30 546.10 486.00 ‘OIL_C300’  1.511500  1.515000  1.518000  1.523800 REFRACTIVE INDICES GLASS CODE 587.56 546.07 486.13 WATER_SPECIAL  1.333041  1.334468  1.337129 ‘OIL_C300’  1.515107  1.518002  1.523784 831850.442022  1.831850  1.836320  1.845073 826663.446181  1.826663  1.831064  1.839677 619352.335615  1.619352  1.623721  1.632414 804000.466000  1.804000  1.808101  1.816103 847000.238000  1.847000  1.855385  1.872415 883000.407000  1.883000  1.888148  1.898279 743005.490167  1.743005  1.746611  1.753622 847000.238000  1.847000  1.855385  1.872415 847000.238000  1.847000  1.855385  1.872415 810665.459949  1.810665  1.814854  1.823034 710425.287412  1.710425  1.716265  1.727990 874782.351787  1.874782  1.880672  1.892362 606913.346451  1.606913  1.611062  1.619302 801337.249239  1.801337  1.808918  1.824269 883000.407000  1.883000  1.888148  1.898279 847000.238000  1.847000  1.855385  1.872415 883000.407000  1.883000  1.888148  1.898279 883000.407000  1.883000  1.888148  1.898279 816295.245301  1.816295  1.824139  1.840040 883000.407000  1.883000  1.888148  1.898279 862411.292604  1.862411  1.869376  1.883345 847000.238000  1.847000  1.855385  1.872415 831568.442245  1.831568  1.836035  1.844779 847000.238000  1.847000  1.855385  1.872415 625000.475000  1.625000  1.628129  1.634225 883000.407000  1.883000  1.888148  1.898279 720856.500684  1.720856  1.724282  1.730932 SFPL53_OHARA  1.438750  1.439854  1.441954 No solves defined in system No pickups defined in system POS 1 POS 2 POS 3 POS 4 ZOOM DATA FNO 2.95000 3.35000 3.80000 4.95000 VUY F1 −0.3725E−09 −0.3725E−09 −0.3725E−09 −0.3725E−09 VLY F1 −0.3725E−09 −0.3725E−09 −0.3725E−09 −0.3725E−09 VUY F2 −0.09827 −0.06248 −0.03468 −0.04542 VLY F2 −0.06411 0.10522 0.14242 0.19846 VUY F3 −0.37073 −0.19068 −0.08898 −0.11797 VLY F3 0.09219 0.39567 0.31861 0.30004 VUY F4 −0.90283 −0.39973 −0.15147 −0.21248 VLY F4 −0.53512 0.36548 0.40965 0.34965 VUY F5 0.60862 −0.64221 −0.23027 −0.29146 VLY F5 −1.17789 −0.08041 0.41695 0.34991 VUX F1 −0.3725E−09 −0.3725E−09 −0.3725E−09 −0.3725E−09 VLX F1 −0.3725E−09 −0.3725E−09 −0.3725E−09 −0.3725E−09 VUX F2 −0.02268 −0.01653 −0.00864 0.02038 VLX F2 −0.02268 −0.01653 −0.00864 0.02038 VUX F3 −0.08258 −0.05011 −0.02444 0.04722 VLX F3 −0.08258 −0.05011 −0.02444 0.04722 VUX F4 −0.18153 −0.09973 −0.02760 0.06457 VLX F4 −0.18153 −0.09973 −0.02760 0.06457 VUX F5 0.03337 −0.15623 −0.02297 0.06533 VLX F5 0.03337 −0.15623 −0.02297 0.06533 RSL DEF DEF DEF DEF RDY S16 −11.43113 −2459.58467 55.73115 14.41014 CCY S16 100 100 100 100 THI 823 2.67790 4.72540 4.78059 3.62845 THC S23 100 100 100 100 RDY S24 8.85890 14.00299 −87.21004 −13.92795 CCY S24 100 100 100 100 THI S24 3.81859 1.77108 1.71591 2.86805 THC S24 100 100 100 100 THI S54 0.69672 0.70286 1.09831 3.56852 THC S54 100 100 100 100 RDY S55 14.53352 13.05053 −23.93138 −10.58463 CCY S55 100 100 100 100 THI S55 9.52943 9.52332 9.12788 6.65769 THC 855 100 100 100 100 INFINITE CONJUGATES EFL −7.3510 −10.2999 −15.4979 −22.0460 BFL −0.0043 0.0045 0.0145 −0.0292 FFL 19.5007 15.6388 10.7495 0.5985 FNO −2.9500 −3.3499 −3.7997 −4.9490 AT USED CONJUGATES RED −0.0001 −0.0001 −0.0002 −0.0002 FNO −2.9500 −3.3500 −3.8000 −-4.9500 OBJ DIS 99999.0000 99999.0000 99999.0000 99999.0000 TT 0.1001E+06 0.1001E+06 0.1001E+06 0.1001E+06 IMG DIS 0.0000 0.0000 0.0000 0.0000 OAL 150.0000 150.0000 150.0001 150.0001 PARAXIAL IMAGE HT 5.5252 5.7287 5.6590 5.3565 THI −0.0037 0.0056 0.0169 −0.0244 ANG 36.9280 29.0809 20.0576 13.6536 ENTRANCE PUPIL DIA 2.4919 3.0747 4.0787 4.4546 THI 20.8582 18.2119 19.2553 20.2354 EXIT PUPIL DIA 13.4937 12.3078 7.4316 5.0011 THI −39.8101 −41.2256 −28.2232 −24.7799 STO DIA 10.2981 8.7930 9.2582 7.4061 FABRICATION DATA 28-Mar-09 CLZ6mmMockUpV050T1 ELEMENT RADIUS OF CURVATURE APERTURE DIAMETER NUMBER FRONT BACK THICKNESS FRONT BACK GLASS OBJECT INF 99999.0000 38.8263   5.0000  1 A(1) −27.9953 CX   9.0384 27.9317 23.0069 883.407  2 −27.9953 CC 5.8056 CC   2.4069 23.0069  9.3414 606.346   3.9052  3 −8.1293 CC −9.2981 CX   0.7000  9.1160 11.2000 847.238   0.0999  4 45.5925 CX −21.7998 CX   1.1840  7.7995  7.4225 883.407   4.2201  5 −34.7541 CC −8.7718 CX   1.2649  6.5172  6.9511 883.407  6 −8.7718 CC −13.0559 CX   0.7000  6.9511  5.2200 710.287   0.1000  7 26.6607 CX 11.5414 CC   0.7000  8.0373  8.3362 816.245   0.6665  8 35.2888 CX INF   0.9623  8.5905  8.9896 883.407  9 INF −11.4311*2   4.6043  8.9896 11.0000 720.500 10 −11.4311*2 INF   3.7049 11.0000 14.4467 WATER 11 INF −29.8341 CX   1.6292 14.4467 14.7767 874.351   12.0970 21.1721   0.7050 12 32.4222 CX −36.1226 CX   6.3560 22.9604 22.8495 862.292   9.2664 13 23.5982 CX 0.1000E+19 CC   2.5578 15.7056 14.9824 831.442 14 0.1000E+19 CX 8.8589*3   2.6779*4 14.9824 11.0000 625.475 15 8.8589*3 INF   3.8186*5 11.0000 11.0000 WATER 16 INF 12.9087 CC   0.7000 11.0000 11.0000 847.238   0.9928 17 93.0154 CX −7.5206 CX   2.6090  9.8066  9.7162 831.442 18 −7.5206 CC −15.0239 CX   7.6388  9.7162  8.7570 847.238   2.3714 19 −7.0172 CC 30.4662 CC   0.7000  7.1757  7.5437 801.249   2.0029 20 −29.1874 CC −19.9035 CX   0.9201  8.4800  8.9219 826.446 21 −19.9035 CC −11.3479 CX   1.1917  8.9219  9.3077 WATER 22 −11.3479 CC −8.3803 CX   1.2827  9.3077  9.7693 883.407 23 −8.3803 CC 162.4970 CC   0.7029  9.7693 10.2981 619.335 APERTURE STOP 10.2981   0.1416 24 127.1032 CX −10.8390 CX   2.5747 11.2083 11.5666 804.466   0.1000 25 24.6341 CX 281.8260 CC   1.3325 11.5891 11.5054 847.238   1.9782 11.1458   0.0000 11.1458   0.0000 11.1458   12.5011 26 −13.5481 CC −15.6702 CX   5.6469 11.0000 11.8604 883.407   0.1131 27 24.6556 CX −16.5124 CX   2.5475 12.0054 11.8848 743.490   0.1921 28 −15.6685 CC 69.9180 CC   0.7000 11.7026 11.5015 847.238 29 69.9180 CX 7.1824 CC   0.7000 11.5015 11.2757 WATER 30 7.1824 CX −19.7354 CX   4.2187 11.2757 11.0388 ‘OIL_C300’ 31 −19.7354 CC 11.4488 CC   0.7000 11.0388 10.5853 847.238   0.7138 32 19.8521 CX INF   1.4362 10.6893 10.7552 810.459 33 INF 14.5335*1   0.6967*6 10.7552 11.0000 WATER 34 14.5335*1 INF   9.5294*7 11.0000 10.9825 ‘OIL_C300’ 35 INF A(2)   0.7000 10.9825 10.9807 SFPL53 Ohara   4.0000 11.0135 IMAGE DISTANCE =   0.0000 IMAGE INF 11.0135 NOTES Positive radius indicates the center of curvature is to the right Negative radius indicates the center of curvature is to the left Dimensions are given in millimeters Thickness is axial distance to next surface Image diameter shown above is a paraxial value, it is not a ray traced value Other glass suppliers can be used if their materials are functionally equivalent to the extent needed by the design; contact the designer for approval of substitutions. ASPHERIC CONSTANTS $Z = {\frac{({CURV})Y^{2}}{1 + \left( {1 - {\left( {1 + K} \right)\mspace{11mu} {({CURV})\;}^{2}Y^{2}}} \right)^{1/2}} + {(A)Y^{4}} + {(B)Y^{6}} + {(C)Y^{8}} + {(D)Y^{10}}}$ ASPHERIC CURV K A B C D A(1) 0.04350670 0.000000 −3.52307E−05   3.26666E-09 −1.06122E−10 0.00000E+00 A(2) 0.01485731 0.000000 −8.35273E−05 −2.32025E−06   4.05318E−08 0.00000E+00 REFERENCE WAVELENGTH = 546.1 NM SPECTRAL REGION = 486.1-587.6 NM POS. 1 POS. 2 POS. 3 POS. 4 * ZOOM PARAMETERS *1 = 14.5335 13.0505 −23.9314 −10.5846 *2 = −11.4311 −2459.5847 55.7311 14.4101 *3 = 8.8589 14.0030 −87.2100 −13.9279 *4 = 2.6779 4.7254 4.7806 3.6284 *5 = 3.8186 1.7711 1.7159 2.8681 *6 = 0.6967 0.7029 1.0983 3.5685 *7 = 9.5294 9.5233 9.1279 6.6577 INFINITE CONJUGATES EFL = −7.3510 −10.2999 −15.4979 −22.0460 BFL = −0.0043 0.0045 0.0145 −0.0292 FFL = 19.5007 15.6388 10.7495 0.5985 F/NO = −2.9500 −3.3499 −3.7997 −4.9490 AT USED CONJUGATES REDUCTION = −0.0001 −0.0001 −0.0002 −0.0002 FINITE F/NO = −2.9500 −3.3500 −3.8000 −4.9500 OBJECT DIST = 99999.0000 99999.0000 99999.0000 99999.0000 TOTAL TRACK = 100149.0000 100149.0000 100149.0001 100149.0001 IMAGE DIST = 0.0000 0.0000 0.0000 0.0000 OAL = 150.0000 150.0000 150.0001 150.0001 PARAXIAL IMAGE HT = 5.5252 5.7287 5.6590 5.3565 IMAGE DIST = −0.0037 0.0056 0.0169 −0.0244 SEMI-FIELD ANGLE = 36.9280 29.0809 20.0576 13.6536 ENTR PUPIL DIAMETER = 2.4919 3.0747 4.0787 4.4546 DISTANCE = 20.8582 18.2119 19.2553 20.2354 EXIT PUPIL DIAMETER = 13.4937 12.3078 7.4316 5.0011 DISTANCE = −39.8101 −41.2256 −28.2232 −24.7799 APER STOP DIAMETER = 10.2981 8.7930 9.2582 7.4061 NOTES FFL is measured from the first surface BFL is measured from the last surface

APPENDIX 6 3 Cell - Stop in Objective CLZ6mmMockUpV050T2frtstpREV1 RDY  THI   RMD GLA CCY THC GLC > OBJ: INFINITY 99999.000000 100 100  1: INFINITY 5.000000 100 100  2: 27.17499 5.740859 883000.407000 100 100 100 ASP: K: 0.000000 KC: 100 IC: YES CUF: 0.000000 CCF: 100 A: −.729458E−04 B: −.162574E−06 C: 0.138436E−08 D: 0.000000E+00 AC: 100 BC: 100 CC: 100 DC: 100  3: −19.62258 1.043590 562252.432160 100 100 100  4: 6.38442 3.943724 100 100  5: −6.82177 0.700000 839185.239767 100 100 100  6: −8.13566 0.100000 100 100  7: −15.95799 0.995456 883000.407000 100 100 100  8: −21.79978 1.487626 100 100 STO: INFINITY 2.520067 100 100 10: −36.84479 1.471973 856654.423794 100 100 100 11: −5.85553 0.700000 868199.319387 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 12: −12.43516 0.100000 100 100 13: 32.91186 0.700000 845938.238237 100 100 100 14: 12.10914 0.732916 100 100 15: 89.91692 0.794602 883000.407000 100 100 100 16: INFINITY 4.610198 804000.466000 100 100 100 GP1: SPSL7_OHARA SPG: PRC: 17: −11.38457 6.177779 WATER SPECIAL 100 100 18: INFINITY 1.830118 847000.238000 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 19: −30.46592 14.559945 100 100 20: INFINITY 0.704953 100 100 21: 25.32699 5.805956 842389.239035 100 100 100 22: −124.38573 9.824847 100 100 23: 16.14665 3.449147 843480.433150 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 24: INFINITY 4.735591 647730.358259 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 25: 7.46903 1.390386 WATER SPECIAL 100 100 26: INFINITY 0.700000 847000.238000 100 100 100 27: 8.60119 0.761142 100 100 28: 16.89436 3.745287 804158.356303 100 100 100 GP1: SESL7_OHARA SPG: PRC: 29: −5.89841 10.000000 796874.250467 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 30: −17.87685 0.534387 100 100 31: −8.63490 0.760839 823863.250497 100 100 100 32: 24.26056 1.929188 100 100 33: −19.89659 0.762149 847000.238000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 34: −19:43112 1.189292 WATER SPECIAL 100 100 35: −11.24916 1.294340 862442.419897 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 36: −8.34555 0.700000 626961.399191 100 100 100 GP1: SBSLT_OHARA SPG: PRC: 37: 215.43535 0.173924 100 100 38: 91.90179 2.651210 800146.467352 100 100 100 GP1: SLAR65_OHARA SPG: PRC: 39: −11.32456 0.100000 100 100 40: 26.04968 1.294308 847000.238000 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 41: 186.98633 1.978245 100 100 42: INFINITY 0.000000 100 100 43: INFINITY 0.000000 100 100 44: INFINITY 12.500048 100 100 45: −74.67815 1.736873 815446.455638 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 46: −29.35702 0.100000 100 100 47: 61.72280 1.849240 755148.4848.38 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 48: −18.76283 0.326206 100 100 49: −15.42441 0.700000 847000.238000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 50: −889.03425 0.700000 WATER SPECIAL 100 100 51: 7.40337 3.825112 ‘OIL -C300’ 100 100 52: −27.28137 0.700000 823772.243432 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 53: 11.08950 0.496135 100 100 54: 14.71611 1.740142 821534.450424 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 55: INFINITY 0.701134 WATER SPECIAL 100 100 56: 15.61672 10.733382 ‘OIL C300’ 100 100 57: INFINITY 2.197682 SFPL53_OHARA 100 100 58: 15.32749 4.000000 100 100 ASP: K: 0.000000 KC: 100 IC: YES CUF: 0.000000 CCF: 100 A: −.112838E−-03 B: −.371254E−05 C: 0.437605E−07 D: 0.000000E+00 AC: 100 BC: 100 CC: 100 DC: 100 59: INFINITY 0.000000 100 100 IMG: INFINITY 0.000000 100 100 SPECIFICATION DATA FNO 2.95000 DIM MM WL 587.56 546.07 486.13 REF 2 WTW 88  99    77   INI IAN XRI 0.00000 0.00000 0.00000 0.00000 0.00000 YRI 0.00000 2.20000 3.57500 4.67500 5.50000 WTF 1.00000 1.00000 1.00000 1.00000 1.00000 VUY 0.00000 0.00000 0.00000 0.00000 0.00000 VLY 0.00000 0.00000 0.00000 0.00000 0.00000 POL N APERTURE DATA/EDGE DEFINITIONS CA APE APERTURE data not specified for surface Obj thru 60 PRIVATE CATALOG PWL 656.30 589.30 546.10 486.00 ‘OIL_C300’  1.511500  1.515000  1.518000  1.523800 REFRACTIVE INDICES GLASS CODE 587.56 546.07 486.13 WATER_SPECIAL  1.333041  1.334468  1.337129 ‘OIL_C300’  1.515107  1.518002  1.523784 804158.356303  1.804158  1.809505  1.820109 847000.238000  1.847000  1.855385  1.872415 626961.399191  1.626961  1.630687  1.638028 800146.467352  1.800146  1.804216  1.812156 847000.238000  1.847000  1.855385  1.872415 815446.455638  1.815446  1.819699  1.828009 755148.484838  1.755148  1.758852  1.766060 847000.238000  1.847000  1.855385  1.872415 823772.243432  1.823772  1.831749  1.847924 821534.450424  1.821534  1.825868  1.834342 868199.319387  1.868199  1.874631  1.887464 847000.238000  1.847000  1.855385  1.872415 562252.432160  1.562252  1.565342  1.571399 823863.250497  1.823863  1.831619  1.847319 883000.407000  1.883000  1.888148  1.898279 839185.239767  1.839185  1.847433  1.864175 883000.407000  1.883000  1.888148  1.898279 856654.423794  1.856654  1.861453  1.870874 845938.238237  1.845938  1.854304  1.871295 883000.407000  1.883000  1.888148  1.898279 842389.239035  1.842389  1.850693  1.867554 847000.238000  1.847000  1.855385  1.872415 843480.433150  1.843480  1.848105  1.857170 796874.250467  1.796874  1.804376  1.819564 647730.358259  1.647730  1.652014  1.660506 862442.419897  1.862442  1.867318  1.876895 804000.466000  1.804000  1.808101  1.816103 SFPL53_OHARA  1.438750  1.439854  1.441954 No solves defined in system No pickups defined in system POS 1 POS 2 POS 3 POS 4 ZOOM DATA FNO 2.95000 3.35000 3.80000 4.95000 VUY Fl 0.00000 0.00000 0.00000 0.00000 VLY Fl 0.00000 0.00000 0.00000 0.00000 VUY F2 0.00000 0.00000 0.00000 0.00000 VLY F2 0.00000 0.00000 0.00000 0.00000 VUY F3 0.00000 0.00000 0.00000 0.00000 VLY F3 0.00000 0.00000 0.00000 0.00000 VUY F4 0.00000 0.00000 0.00000 0.00000 VLY F4 0.00000 0.00000 0.00000 0.00000 VUY F5 0.00000 0.00000 0.00000 0.00000 VLY F5 0.00000 0.00000 0.00000 0.00000 VUX Fl 0.00000 0.00000 0.00000 0.00000 VLX Fl 0.00000 0.00000 0.00000 0.00000 VUX F2 0.00000 0.00000 0.00000 0.00000 VLX F2 0.00000 0.00000 0.00000 0.00000 VUX F3 0.00000 0.00000 0.00000 0.00000 VLX F3 0.00000 0.00000 0.00000 0.00000 VUX F4 0.00000 0.00000 0.00000 0.00000 VLX F4 0.00000 0.00000 0.00000 0.00000 VUX F5 0.00000 0.00000 0.00000 0.00000 VLX F5 0.00000 0.00000 0.00000 0.00000 RSL DEF DEF DEF DEF RDY S17 −11.38457 −16.73777 −-52.22048 37.13744 CCY S17 100 100 100 100 THI S24 4.73559 3.35122 4.01960 2.81318 THC S24 100 100 100 100 RDY S25 7.46903 15.02906 −1529.63217 −18.28562 CCY S25 100 100 100 100 THI S25 1.39039 2.77475 2.10641 3.31283 THC S25 100 100 100 100 THI S55 0.70113 1.89798 1.22023 8.67162 THC S55 100 100 100 100 RDY S56 15.61672 127.28013 −24.40461 −10.96839 CCY S56 100 100 100 100 THI S56 10.73338 9.53656 10.21431 2.76295 THC S56 100 100 100 100 INFINITE CONJUGATES EFL −7.3514 −10.3000 −15.5003 −-22.0489 BFL 0.0138 0.0487 0.0078 −0.0400 FFL 12.7504 10.0449 3.7402 −8.2886 FNO −2.9499 −3.3498 −3.7995 −4.9488 AT USED CONJUGATES RED −0.0001 −0.0001 −-0.0002 −0.0002 FNO −2.9500 −3.3500 −3.8000 −4.9500 OBJ DIS 99999.0000 99999.0000 99999.0000 99999.0000 TT 0.1001E+06 0.1001E+06 0.1001E+06 0.1001E+06 IMG DIS 0.0000 0.0000 0.0000 0.0000 OAL 150.0000 150.0000 150.0001 150.0001 PARAXIAL IMAGE HT 5.6950 5.7362 5.6134 5.3548 THI 0.0143 0.0497 0.0102 −0.0352 ANG 37.7636 29.1124 19.9054 13.6474 ENTRANCE PUPIL DIA 2.4921 3.0748 4.0795 4.4554 THI 16.1264 16.1264 16.1264 16.1264 EXIT PUPIL DIA 5.4265 5.2077 5.1052 4.0236 THI −15.9940 −17.3962 −19.3895 −19.9521 STO DIA 2.5715 3.1787 4.2355 4.6349 FABRICATION DATA 28-Mar-09 CLZ6mmMockUpV050T2frtstpREV1 ELEMENT RADIUS OF CURVATURE APERTURE DIAMETER NUMBER FRONT BACK THICKNESS FRONT BACK GLASS OBJECT INF 99999.0000 26.2363   5.0000  1 A(1) −19.6226 CX   5.7409 17.0034 13.9972 883.407  2 −19.6226 CC 6.3844 CC   1.0436 13.9972  8.3063 562.432   3.9437  3 −-6.8218 CC −8.1357 CX   0.7000  6.0039  6.0824 839.239   0.1000  4 106.8119 CX −15.9580 CX   0.9955  5.8334  5.6898 883.407   1.4876 APERTURE STOP  4.6349   2.5201  5 −36.8448 CC −5.8555 CX   1.4720  5.6969  6.1801 856.423  6 −5.8555 CC −12.4352 CX   0.7000  6.1801  6.9547 868.319   0.1000  7 32.9119 CX 12.1091 CC   0.7000  7.6366  7.9873 845.238   0.7329  8 89.9169 CX INF   0.7946  8.2471  8.7226 883.407  9 INF −11.3846*2   4.6102  8.7226 11.0000 804.466 10 −11.3846*2 INF   6.1778 11.0000 15.4386 WATER 11 INF −30.4659 CX   1.8301 15.4386 15.7651 847.238   14.5599 21.5863   0.7050 12 25.3270 CX −124.3857 CX   5.8060 23.4480 22.9166 842.239   9.8248 13 16.1467 CX 0.1000E+19 CC   3.4491 15.5663 14.3817 843.433 14 0.1000E+19 CX 7.4690*3   4.7356*4 14.3817 11.0001 647.358 15 7.4690*3 INF   1.3904*5 11.0001  9.6872 WATER 16 INF 8.6012 CC   0.7000  9.6872  8.6961 847.238   0.7611 17 16.8944 CX −5.8984 CX   3.7453  8.6938  8.3393 804.356 18 −5.8984 CC −17.8769 CX   10.0000  8.3393  6.9911 796.250   0.5344 19 −8.6349 CC 24.2606 CC   0.7608  6.9471  7.3745 823.250   1.9292 20 −19.8966 CC −19.4311 CX   0.7621  8.2942  8.7178 847.238 21 −19.4311 CC −11.2492 CX   1.1893  8.7178  9.1821 WATER 22 −11.2492 CC −8.3455 CX   1.2943  9.1821  9.7027 862.419 23 −8.3455 CC 215.4354 CC   0.7000  9.7027 11.1757 626.399   0.1739 24 91.9018 CX −11.3246 CX   2.6512 11.5099 11.9145 800.467   0.1000 25 26.0497 CX 186.9863 CC   1.2943 11.8795 11.7241 847.238   1.9782 11.0427   0.0000 11.0427   0.0000 11.0427   12.5000 26 −74.6781 CC −29.3570 CX   1.7369 11.5229 11.6484 815.455   0.1000 27 61.7228 CX −18.7628 CX   1.8492 11.4893 11.3663 755.484   0.3262 28 −15.4244 CC −889.0343 CX   0.7000 11.2263 11.1283 847.238 29 −889.0343 CC 7.4034 CC   0.7000 11.1283 11.1995 WATER 30 7.4034 CX −27.2814 CX   3.8251 11.1995 11.0409 ‘OIL_C300’ 31 −27.2814 CC 11.0895 CC   0.7000 11.0409 10.7375 823.243   0.4961 32 14.7161 CX INF   1.7401 10.8685 10.8983 821.450 33 INF 15.6167*1   0.7011*6 10.8983 10.9976 WATER 34 15.6167*1 INF   10.7334*7 10.9976 10.6098 ‘OIL_C300’ 35 INF A(2)   2.1977 10.6098 10.4844 SFPL53 Ohara   4.0000 11.0088 IMAGE DISTANCE =   0.0000 IMAGE INF 11.0088 NOTES Positive radius indicates the center of curvature is to the right Negative radius indicates the center of curvature is to the left Dimensions are given in millimeters Thickness is axial distance to next surface Image diameter shown above is a paraxial value, it is not a ray traced value Other glass suppliers can be used if their materials are functionally equivalent to the extent needed by the design; contact the designer for approval of substitutions. ASPHERIC CONSTANTS $Z = {\frac{({CURV})Y^{2}}{1 + \left( {1 - {\left( {1 + K} \right)\mspace{11mu} {({CURV})\;}^{2}Y^{2}}} \right)^{1/2}} + {(A)Y^{4}} + {(B)Y^{6}} + {(C)Y^{8}} + {(D)Y^{10}}}$ ASPHERIC CURV K A B C D A(1) 0.03679854 0.000000 −7.29458E−05 −1.62574E−07 1.38436E−09 0.00000E+00 A(2) 0.06524226 0.000000 −1.12838E−04 −3.71254E−06 4.37605E−08 0.00000E+00 REFERENCE WAVELENGTH = 546.1 NM SPECTRAL REGION = 486.1 − 587.6 NM POS. 1 POS. 2 POS. 3 POS. 4 * ZOOM PARAMETERS *1 = 15.6167 127.2801 −24.4046 −10.9684 *2 = −11.3846 −16.7378 −52.2205 37.1374 *3 = 7.4690 15.0291 −1529.6322 −18.2856 *4 = 4.7356 3.3512 4.0196 2.8132 *5 = 1.3904 2.7748 2.1064 3.3128 *6 = 0.7011 1.8980 1.2202 8.6716 *7 = 10.7334 9.5366 10.2143 2.7630 INFINITE CONJUGATES EFL = −7.3514 −10.3000 −15.5003 −22.0489 BFL = 0.0138 0.0487 0.0078 −0.0400 FFL = 12.7504 10.0449 3.7402 −8.2886 F/NO = −2.9499 −3.3498 −3.7995 −4.9488 AT USED CONJUGATES REDUCTION = −0.0001 −0.0001 −0.0002 −0.0002 FINITE F/NO = −2.9500 −3.3500 −3.8000 −4.9500 OBJECT DIST = 99999.0000 99999.0000 99999.0000 99999.0000 TOTAL TRACK = 100149.0000 100149.0000 100149.0001 100149.0001 IMAGE DIST = 0.0000 0.0000 0.0000 0.0000 OAL = 150.0000 150.0000 150.0001 150.0001 PARAXIAL IMAGE HT = 5.6950 5.7362 5.6134 5.3548 IMAGE DIST = 0.0143 0.0497 0.0102 −0.0352 SEMI-FIELD ANGLE = 37.7636 29.1124 19.9054 13.6474 ENTR PUPIL DIAMETER = 2.4921 3.0748 4.0795 4.4554 DISTANCE = 16.1264 16.1264 16.1264 16.1264 EXIT PUPIL DIAMETER = 5.4265 5.2077 5.1052 4.0236 DISTANCE = −15.9940 −17.3962 −19.3895 −19.9521 APER STOP DIAMETER = 2.5715 3.1787 4.2355 4.6349 NOTES FFL is measured from the first surface BFL is measured from the last surface

APPENDIX 7 2 Cell - Stop in Objective CLZ6mmMockUp2cV03 RDY  THI   RMD GLA CCY THC GLC > OBJ: INFINITY 99999.000000 100 100  1: 29.97822 6.126371 831140.442583 100 100 100 ASP: K: 0.000000 KC: 100 IC: YES CUF: 0.000000 CCF: 100 A: −.486937E−04 B: −.439186E−07 C: 0.173590E−09 D: 0.000000E+00 AC: 100 BC: 100 CC: 100 DC: 100  2: −22.05286 1.013967 564056.394655 100 100 100  3: 6.99927 4.265487 100 100  4: −9.39271 0.700000 540641.431476 100 100 100  5: −11.68149 0.100000 100 100  6: −84.98429 1.063401 883000.407000 100 100 100 11 7: −16.39952 3.516724 100 100 STO: INFINITY 2.520067 100 100  9: 302.42727 2.475833 842724.433709 100 100 100 10: −4.84627 0.700000 874402.349574 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 11: −13.49699 0.741416 100 100 12: 21.50680 1.787460 841230.239299 100 100 100 13: 11.20575 1.007399 100 100 14: −156.47454 0.700000 883000.407000 100 100 100 15: INFINITY 4.440210 883000.407000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 16: −12.73200 5.560110 WATER_SPECIAL 100 100 17: INFINITY 2.092617 848536.242470 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 18: −21.53936 18.952916 100 100 19: INFINITY 0.704953 100 100 20: 62.85853 4.788004 880815.390803 100 100 100 21: −34.41579 12.539136 100 100 22: 13.70990 2.751675 677262.306457 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 23: INFINITY 3.815471 650000.350000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 24: 8.24896 2.911048 WATER_SPECIAL 100 100 25: INFINITY 0.700000 847630.239816 100 100 100 26: 8.51496 0.976119 100 100 27: 20.04988 3.674558 808267.424929 100 100 100 GP1: SESL7_OHARA SPG: PRC: 28: −5.37360 0.700000 796055.455996 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 29: −18.40723 0.699292 100 100 30: −8.98142 0.700000 807334.247627 100 100 100 31: 27.56843 1.910484 100 100 32: −18.17344 0.780019 847000.238000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 33: −17.31818 1.212127 WATER_SPECIAL 100 100 34: −11.48640 1.353511 855732.424426 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 35: −8.63609 0.700999 627374.329192 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 36: 583.40295 0.143056 100 100 37: 87.02895 2.635317 799189.467691 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 38: −12.67392 0.100000 100 100 39: 64.39662 1.323318 847000.238000 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 40: −49.94324 1.978245 100 100 41: INFINITY 0.000000 100 100 42: INFINITY 0.000000 100 100 43: INFINITY 12.508243 100 100 44: −147.75915 1.372231 831945.441947 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 45: −25.36493 0.100000 100 100 46: 65.25467 1.903707 777379.475785 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 47: −21.05549 0.318012 100 100 48: −16.80579 0.700000 831922.241463 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 49: 501.49643 0.700000 WATER_SPECIAL 100 100 50: 7.61290 3.757704 ‘OIL_C300’ 100 100 51: −67.93899 0.700000 795249.250921 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 52: 10.77423 0.757193 100 100 53: 18.76646 1.666944 824004.448364 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 54: −66.13508 8.728731 WATER_SPECIAL 100 100 55: −20.00000 1.629872 ‘OIL_C300’ 100 100 56: 13.97568 1.295557 SFPL53_OHARA 100 100 57: 34.51546 4.000499 100 100 ASP: K: 0.000000 KC:100 IC: YES CUF: 0.000000 CCF: 100 A: 0.809163E−04 B: −.498451E−05 C: 0.185988E−07 D: 0.000000E+00 AC: 100 BC: 100 CC: 100 DC: 100 58: INFINITY 0.000000 100 100 IMG: INFINITY 0.000000 100 100 SPECIFICATION DATA FNO 2.95000 DIM MM WL 587.56 546.07 486.13 REF 2 WTW 88  99    77   INI IAN XRI 0.00000 0.00000 0.00000 0.00000 0.00000 YRI 0.00000 2.20000 3.57500 4.67500 5.50000 WTF 1.00000 1.00000 1.00000 1.00000 1.00000 VUX 0.00000 0.00052 −0.00244 −0.01030 −0.02066 VLX 0.00000 0.00052 −0.00244 −0.01030 −0.02066 VUY 0.00000 −0.00256 −0.03188 −0.10179 0.15365 VLY 0.00000 0.00063 −0.01257 −0.05362 0.47939 POL N APERTURE DATA/EDGE DEFINITIONS CA APE CIR S1  9.496272 CIR S57  5.094540 PRIVATE CATALOG PWL 656.30 589.30 546.10 486.00 ‘OIL_C300’ 1.511500  1.515000  1.518000  1.523800 REFRACTIVE INDICES GLASS CODE 587.56 546.07 486.13 WATER_SPECIAL  1.333041  1.334468  1.337129 ‘OIL_C300’  1.515107  1.518002  1.523784 808267.424929  1.808267  1.812783  1.821647 847000.238000  1.847000  1.855385  1.872415 627374.329192  1.627374  1.631885  1.640870 799189.467691  1.799189  1.803251  1.811175 847000.238000  1.847000  1.855385  1.872415 831945.441947  1.831945  1.836417  1.845172 777379.475785  1.777379  1.781264  1.788834 831922.241463  1.831922  1.840042  1.856517 795249.250921  1.795249  1.802723  1.817851 824004.448364  1.824004  1.828370  1.836911 874402.349574  1.874402  1.880327  1.892088 848536.242470  1.848536  1.856784  1.873515 564056.394655  1.564056  1.567446  1.574130 807334.247627  1.807334  1.815021  1.830593 831140.442583  1.831140  1.835601  1.844335 540641.431476  1.540641  1.543617  1.549451 883000.407000  1.883000  1.888148  1.898279 842724.433709  1.842724  1.847339  1.856384 841230.239299  1.841230  1.849513  1.866331 883000.407000  1.883000  1.888148  1.898279 880815.390803  1.880815  1.886161  1.896705 847630.239816  1.847630  1.855959  1.872866 677262.306457  1.677262  1.682488  1.692940 796055.455996  1.796055  1.800204  1.808310 650000.350000  1.650000  1.654399  1.663131 855732.424426  1.855732  1.860519  1.869915 883000.407000  1.883000  1.888148  1.898279 SFPL53_OHARA  1.438750  1.439854  1.441954 No solves defined in system No pickups defined in system POS 1 POS 2 POS 3 POS 4 ZOOM DATA FNO 2.95000 3.35000 3.80000 4.95000 VUY Fl −0.3725E−09 −0.3725E−09 −0.3725E−09 −0.3725E−09 VLY Fl −0.3725E−09 −0.3725E−09 −0.3725E−09 −0.3725E−09 VUY F2 −0.00256 0.00012 0.00082 0.00082 VLY F2 0.00063 0.00063 −0.00039 −0.00057 VUY F3 −0.03188 −0.00976 −0.00118 0.00053 VLY F3 −0.01257 −0.00119 0.4435E−04 −0.00045 VUY F4 −0.10179 −0.03215 −0.00611 −0.00066 VLY F4 −0.05362 −0.01081 −0.00016 −0.00023 VUY F5 0.15365 −0.06376 −0.01288 −0.00236 VLY F5 0.47939 −0.02735 −0.00140 −0.00012 VUX Fl −0.3725E−09 −0.3725E−09 −0.3725E−09 −0.3725E−09 VLX Fl −0.3725E−09 −0.3725E−09 −0.3725E−09 −0.3725E−09 VUX F2 0.00052 0.00050 0.00025 0.00014 VLX F2 0.00052 0.00050 0.00025 0.00014 VUX F3 −0.00244 −0.1756E−04 0.00040 0.00028 VLX F3 −0.00244 −0.1756E−04 0.00040 0.00028 VUX F4 −0.01030 −0.00234 0.00021 0.00036 VLX F4 −0.01030 −0.00234 0.00021 0.00036 VUX F5 −0.02066 −0.00589 −0.00028 0.00035 VLX F5 −0.02066 −0.00589 −0.00028 0.00035 RSL DEF DEF DEF DEF RDY S16 −12.73200 −50.59980 28.00979 14.77275 CCY S16 100 100 100 100 THI S23 3.81547 2.58830 5.19232 2.77536 THC S23 100 100 100 100 RDY S24 8.24896 11.22109 29.32310 −27.47395 CCY S24 100 100 100 100 THI S24 2.91105 4.13819 1.53420 3.95115 THC S24 100 100 100 100 INFINITE CONJUGATES EFL −7.8524 −10.3484 −15.8485 −21.9962 BFL −0.0026 0.0198 0.0478 −0.0049 FFL 10.8221 6.4794 −1.7823 −9.6256 FNO −2.9499 −3.3498 −3.7994 −4.9489 AT USED CONJUGATES RED −0.0001 −0.0001 −0.0002 −0.0002 FNO −2.9500 −3.3500 −3.8000 −4.9500 OBJ DIS 99999.0000 99999.0000 99999.0000 99999.0000 TT 0.1001E+06 0.1001E+06 0.1001E+06 0.1001E+06 IMG DIS 0.0000 0.0000 0.0000 0.0000 OAL 145.0000 145.0000 145.0000 145.0000 PARAXIAL IMAGE HT 5.7515 5.7219 5.6141 5.3788 THI −0.0020 0.0208 0.0503 0.0000 ANG 36.2202 28.9378 19.5032 13.7380 ENTRANCE PUPIL DIA 2.6619 3.0893 4.1713 4.4447 THI 13.1968 13.1968 13.1968 13.1968 EXIT PUPIL DIA 8.8021 4.7591 4.4134 4.2838 THI −25.9682 −15.9221 −16.7205 −21.2049 STO DIA 2.8742 3.3403 4.5316 4.8358 FABRICATION DATA 28-Mar-09 CLZ6mmMockUp2cV03 APERTURE ELEMENT RADIUS OF CURVATURE DIAMETER NUMBER FRONT BACK THICKNESS FRONT BACK GLASS OBJECT INF 99999.0000  1 A(1) −22.0529 CX   6.1264 18.9925 15.9632 831.442  2 −22.0529 CC 6.9993 CC   1.0140 15.9632  9.8352 564.394   4.2655  3 −9.3927 CC −11.6815 CX   0.7000  8.5396  8.3728 540.431   0.1000  4 −84.9843 CC −16.3995 CX   1.0634  7.7489  7.4975 883.407   3.5167 APERTURE STOP 4.8358   2.5201  5 302.4273 CX −4.8463 CX   2.4758  6.0930  6.4749 842.433  6 −4.8463 CC −13.4970 CX   0.7000  6.4749  7.1194 874.349   0.7414  7 21.5068 CX 11.2058 CC   1.7875  7.9997  8.2350 841.239   1.0074  8 −156.4745 CC INF   0.7000  8.4189  8.8416 883.407  9 INF −12.7320*1   4.4402  8.8416 11.0000 883.407 10 −12.7320*1 INF   5.5601 11.0000 14.9522 WATER 11 INF −21.5394 CX   2.0926 14.9522 15.2385 848.242   18.9529 21.3930   0.7050 12 62.8585 CX −34.4158 CX   4.7880 22.2638 22.4336 880.390   12.5391 13 13.7099 CX 0.1000E+19 CC   2.7517 14.8548 14.4947 677.306 14 0.1000E+19 CX 8.2490*2   3.8155*3 14.4947 10.9443 650.350 15 8.2490*2 INF   2.9110*4 10.9443 10.0593 WATER 16 INF 8.5150 CC   0.7000 10.0593  9.0556 847.239   0.9761 17 20.0499 CX −5.3736 CX   3.6746  9.0758  8.9641 808.424 18 −5.3736 CC −18.4072 CX   0.7000  8.9641  8.5060 796.455   0.6993 19 −8.9814 CC 27.5684 CC   0.7000  8.3821  8.6169 807.247   1.9105 20 −18.1734 CC −17.3182 CX   0.7800  9.0980  9.4484 847.238 21 −17.3182 CC −11.4864 CX   1.2121  9.4484  9.8121 WATER 22 −11.4864 CC −8.6361 CX   1.3535  9.8121 10.2699 855.424 23 −8.6361 CC 583.4029 CC   0.7010 10.2699 11.4611 627.329   0.1431 24 87.0290 CX −12.6739 CX   2.6353 11.7312 12.0777 799.467   0.1000 25 64.3966 CX −49.9432 CX   1.3233 11.7687 11.6459 847.238   1.9782 10.9334   0.0000 10.9334   0.0000 10.9334   12.5082 26 −147.7591 CC −25.3649 CX   1.3722 12.4348 12.5100 831.441   0.1000 27 65.2547 CX −21.0555 CX   1.9037 12.2312 12.0728 777.475   0.3180 28 −16.8058 CC 501.4964 CC   0.7000 11.9707 11.7829 831.241 29 501.4964 CX 7.6129 CC   0.7000 11.7829 11.3588 WATER 30 7.6129 CX −67.9390 CX   3.7577 11.3588 11.0007 ‘OIL_C300’ 31 −67.9390 CC 10.7742 CC   0.7000 11.0007 10.3792 795.250   0.7572 32 18.7665 CX −66.1351 CX   1.6669 10.4459 10.4073 824.448 33 −66.1351 CC −20.0000 CX   8.7287 10.4073  9.9840 WATER 34 −20.0000 CC 13.9757 CC   1.6299  9.9840 10.1264 ‘OIL_C300’ 35 13.9757 CX A(2)   1.2956 10.1264 10.1891 SFPL53 Ohara   4.0005 11.0122 IMAGE DISTANCE =   0.0000 IMAGE INF 11.0122 NOTES Positive radius indicates the center of curvature is to the right Negative radius indicates the center of curvature is to the left Dimensions are given in millimeters Thickness is axial distance to next surface Image diameter shown above is a paraxial value, it is not a ray traced value Other glass suppliers can be used if their materials are functionally equivalent to the extent needed by the design; contact the designer for approval of substitutions. ASPHERIC CONSTANTS $Z = {\frac{({CURV})Y^{2}}{1 + \left( {1 - {\left( {1 + K} \right)\mspace{11mu} {({CURV})\;}^{2}Y^{2}}} \right)^{1/2}} + {(A)Y^{4}} + {(B)Y^{6}} + {(C)Y^{8}} + {(D)Y^{10}}}$ ASPHERIC CURV K A B C D A(1) 0.03335755 0.000000 −4.86937E−05 −4.39186E−08 1.73590E−10 0.00000E+00 A(2) 0.02897252 0.000000   8.09163E−05 −4.98451E−06 1.85988E−08 0.00000E+00 REFERENCE WAVELENGTH = 546.1 NM SPECTRAL REGION = 486.1 − 587.6 NM POS. 1 POS. 2 POS. 3 POS. 4 * ZOOM PARAMETERS *1 = −12.7320 −50.5998 28.0098 14.7727 *2 = 8.2490 11.2211 29.3231 −27.4739 *3 = 3.8155 2.5883 5.1923 2.7754 *4 = 2.9110 4.1382 1.5342 3.9512 INFINITE CONJUGATES EFL = −7.8524 −10.3484 −15.8485 −21.9962 BFL = −0.0026 0.0198 0.0478 −0.0049 FFL = 10.8221 6.4794 −1.7823 −9.6256 F/NO = −2.9499 −3.3498 −3.7994 −4.9489 AT USED CONJUGATES REDUCTION = −0.0001 −0.0001 −0.0002 −0.0002 FINITE F/NO = −2.9500 −3.3500 −3.8000 −4.9500 OBJECT DIST = 99999.0000 99999.0000 99999.0000 99999.0000 TOTAL TRACK = 100144.0000 100144.0000 100144.0000 100144.0000 IMAGE DIST = 0.0000 0.0000 0.0000 0.0000 OAL = 145.0000 145.0000 145.0000 145.0000 PARAXIAL IMAGE HT = 5.7515 5.7219 5.6141 5.3788 IMAGE DIST = −0.0020 0.0208 0.0503 0.0000 SEMI-FIELD ANGLE = 36.2202 28.9378 19.5032 13.7380 ENTR PUPIL DIAMETER = 2.6619 3.0893 4.1713 4.4447 DISTANCE = 13.1968 13.1968 13.1968 13.1968 EXIT PUPIL DIAMETER = 8.8021 4.7591 4.4134 4.2838 DISTANCE = −25.9682 −15.9221 −16.7205 −21.2049 APER STOP DIAMETER = 2.8742 3.3403 4.5316 4.8358 NOTES FFL is measured from the first surface BFL is measured from the last surface

APPENDIX 8 2 Cell + 1 Moving Group - Stop in Objective CLZ6mmMockUp2clmV024plt RDY  THI   RMD GLA CCY THC GLC > OBJ: INFINITY 254537.454600 100 100  1: INFINITY 5.000000 100 100  2: 384.21181 14.933248 529479.486790 100 100 100 ASP: K: 0.000000 KC: 100 IC: YES CUF: 0.000000 CCF: 100 A: −.720011E−06 B: 0.840662E−09 C: −.123033E−12 D: 0.000000E+00 AC: 100 BC: 100 CC: 100 DC: 100  3: −66.10894 4.324629 516088.496702 100 100 100  4: 24.83074 29.435153 100 100  5: INFINITY 0.320113 100 100  6: INFINITY 0.100000 100 100  7: 53.63238 12.700000 883000.407000 100 100 100  8: −135.54053 23.543803 100 100 STO: INFINITY 0.100000 100 100 10: 53.47133 3.398315 792569.470072 100 100 100 11: −17.34703 2.718861 851173.250994 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 12: 3614.61128 0.108300 100 100 13: 56.56309 4.754540 733798.271094 100 100 100 14: 21.52031 0.877370 100 100 15: 93.87690 0.913173 882550.407268 100 100 100 16: INFINITY 2.513347 883000.407000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 17: −16.33108 11.487187 WATER_SPECIAL 100 100 18: INFINITY 12.700000 84700.238000 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 19: −39.61552 24.615681 100 100 20: INFINITY 1.794387 100 100 21: 82.67890 6.914119 883000.407000 100 100 100 22: −54.44377 0.638023 100 100 23: 24.40054 12.700000 761927.481920 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 24: INFINITY 10.599322 853614.258391 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 25: 29.66023 2.784834 WATER_SPECIAL 100 100 26: INFINITY 0.700000 883000.407000 100 100 100 27: 11.90308 1.149258 100 100 28: 35.03709 4.911206 776196.411320 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 29: −6.94778 3.885245 769938.266381 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 30: −17.10129 0.553849 100 100 31: −10.80059 2.661860 847000.238000 100 100 100 32: −605.61546 3.928286 100 100 33: −26.99461 1.706504 807001.463209 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 34: −22.62673 0.979873 WATER_SPECIAL 100 100 35: −21.13016 3.434954 824558.447906 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 36: −14.25213 0.700000 637150.321894 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 37: −100.41020 0.311143 100 100 38: −136.95362 5.539385 805213.464865 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 39: −24.49450 0.100000 100 100 40: −76.92881 1.774621 883000.407000 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 41: −41.91475 0.100000 100 100 42: INFINITY 0.000000 100 100 43: INFINITY 0.000000 100 100 44: INFINITY 16.363878 100 100 45: 263.03667 5.131452 841113.434907 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 46: −50.98278 0.100000 100 100 47: 73.59950 5.152828 815501.455589 100 100 100 GP1: SLAH65_OHARA SPG: PRC: 48: −258.56431 0.836484 100 100 49: −130.36584 2.238540 755198.268607 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 50: 4757.94480 0.700000 WATER_SPECIAL 100 100 51: 17.09429 12.452363 ‘OIL_C300’ 100 100 52: −49.34739 4.500217 79874.4.289333 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 53: 18.57949 2.939507 100 100 54: 33.00527 3.067684 804000.466000 100 100 100 GP1: SBSL7_OHARA SPG: PRC: 55: 81.70630 5.117196 WATER_SPECIAL 100 100 56: −26.02233 0.700000 ‘OIL_C300’ 100 100 57: 14.52253 8.190854 SFPL53_OHARA 100 100 58: 29.73759 4.920284 100 100 ASP: K: 0.000000 KC:100 IC: YES CUF: 0.000000 CCF: 100 A: 0.212757E−05 B: −.227939E−06 C: 0.181726E−09 D: 0.000000E+00 AC: 100 BC: 100 CC: 100 DC: 100 59: INFINITY 0.000000 100 100 IMG: INFINITY 0.000000 100 100 SPECIFICATION DATA FRO 2.95000 DIM MM WL 587.56 546.07 486.13 REF 2 WTW 88  99    77   INI IAN XRI 0.00000 0.00000 0.00000 0.00000 0.00000 YRI 0.00000 5.59988 9.09980 11.89974 13.99970 WTF 1.00000 1.00000 1.00000 1.00000 1.00000 VUY 0.00000 0.00000 0.00000 0.00000 0.00000 VLY 0.00000 0.00000 0.00000 0.00000 0.00000 POL N APERTURE DATA/EDGE DEFINITIONS CA APE CIR S54  13.000000 CIR S55  13.000000 CIR S56  13.000000 CIR S57  13.000000 CIR S58  13.000000 PRIVATE CATALOG PWL 656.30 589.30 546.10 486.00 ‘OIL_C300’ 1.511500  1.515000  1.518000  1.523800 REFRACTIVE INDICES GLASS CODE 587.56 546.07 486.13 WATER SPECIAL  1.333041  1.334468  1.337129 ‘OIL_C300’  1.515107  1.518002  1.523784 776196.411320  1.776196  1.780675  1.789482 807001.463209  1.807001  1.811142  1.819225 637150.321894  1.637150  1.641833  1.651175 805213.464865  1.805213  1.809331  1.817365 883000.407000  1.883000  1.888148  1.898279 841113.434907  1.841113  1.845707  1.854708 815501.455589  1.815501  1.819755  1.828067 755198.268607  1.755198  1.761835  1.775212 798744.289333  1.798744  1.805268  1.818358 804000.466000  1.804000  1.808101  1.816103 851173.250994  1.851173  1.859170  1.875357 847000.238000  1.847000  1.855385  1.872415 516088.496702  1.516088  1.518561  1.523362 847000.238000  1.847000  1.855385  1.872415 529479.486790  1.529479  1.532067  1.537099 883000.407000  1.883000  1.888148  1.898279 792569.470072  1.792569  1.796577  1.804393 733798.271094  1.733798  1.740189  1.753062 882550.407268  1.882550  1.887692  1.897811 883000.407000  1.883000  1.888148  1.898279 883000.407000  1.883000  1.888148  1.898279 761927.481920  1.761927  1.765687  1.773006 769938.266381  1.769938  1.776760  1.790518 853614.258391  1.853614  1.861408  1.877155 824558.447906  1.824558  1.828931  1.837487 883000.407000  1.883000  1.888148  1.898279 SFPL53_OHARA  1.438750  1.439854  1.441954 No solves defined in system No pickups defined in system POS 1 POS 2 POS 3 POS 4 ZOOM DATA FNO 2.95000 3.35000 4.45000 4.95000 VUY F1 0.00000 0.00000 0.00000 0.00000 VLY F1 0.00000 0.00000 0.00000 0.00000 VUY F2 0.00000 0.00000 0.00000 0.00000 VLY F2 0.00000 0.00000 0.00000 0.00000 VUY F3 0.00000 0.00000 0.00000 0.00000 VLY F3 0.00000 0.00000 0.00000 0.00000 VUY F4 0.00000 0.00000 0.00000 0.00000 VLY F4 0.00000 0.00000 0.00000 0.00000 VUY F5 0.00000 0.00000 0.00000 0.00000 VLY F5 0.00000 0.00000 0.00000 0.00000 VUX F1 0.00000 0.00000 0.00000 0.00000 VLX F1 0.00000 0.00000 0.00000 0.00000 VUX F2 0.00000 0.00000 0.00000 0.00000 VLX F2 0.00000 0.00000 0.00000 0.00000 VUX F3 0.00000 0.00000 0.00000 0.00000 VLX F3 0.00000 0.00000 0.00000 0.00000 VUX F4 0.00000 0.00000 0.00000 0.00000 VLX F4 0.00000 0.00000 0.00000 0.00000 VUX F5 0.00000 0.00000 0.00000 0.00000 VLX F5 0.00000 0.00000 0.00000 0.00000 RSL DEF DEF DEF DEF THI S16 2.51335 1.38802 3.33172 1.31101 THC S16 100 100 100 100 RDY S17 −16.33108 −31.04791 600.35635 56.05459 CCY S17 100 100 100 100 THI S17 11.48719 12.61632 10.67552 12.70000 THC S17 100 100 100 100 THI S24 10.59932 12.57118 11.91909 12.70000 THC S24 100 100 100 100 RDY S25 29.66023 155.88044 −32.62658 −16.01201 CCY S25 100 100 100 100 THI S25 2.78483 0.82677 1.48744 0.70000 THC S25 100 100 100 100 THI S44 16.36388 17.06712 8.45603 0.10000 THC S44 100 100 100 100 THI S53 2.93951 2.27080 10.75832 19.26505 THC S53 100 100 100 100 INFINITE CONJUGATES EFL −20.0878 −25.9451 −40.0379 −55.7271 BFL 0.0954 −0.0130 −0.0410 0.0934 FFL 41.0941 32.3346 7.1791 −29.6701 FNO −2.9498 −3.3497 −4.4492 −4.9484 AT USED CONJUGATES RED −0.0001 −0.0001 −0.0002 −0.0002 FNO −2.9500 −3.3500 −4.4500 −4.9500 OBJ DIS 0.2545E+06 0.2545E+06 0.2545E+06 0.2545E+06 TT 0.2548E+06 0.2548E+06 0.2548E+06 0.2548E+06 IMG DIS 0.0000 0.0000 0.0000 0.0000 OAL 294.8219 294.8740 294.7619 294.9099 PARAXIAL IMAGE HT 14.0873 14.5930 13.9705 13.7058 THI 0.0969 −0.0103 −0.0347 0.1056 ANG 35.0399 29.3540 19.2322 13.8130 ENTRANCE PUPIL DIA 6.8098 7.7455 8.9990 11.2617 THI 54.4608 54.4608 54.4608 54.4608 EXIT PUPIL DIA 10.2338 9.0823 7.6203 7.4596 THI −30.0928 −30.4361 −33.9449 −36.8194 STO DIA 7.6111 8.6688 10.0930 12.6896 FABRICATION DATA 28-Mar-09 CLZ6mmMockUp2clmV024plt ELEMENT RADIUS OF CURVATURE APERTURE DIAMETER NUMBER FRONT BACK THICKNESS FRONT BACK GLASS OBJECT INF INFINITY 86.5806  5.0000  1 A(1) -66.1089 CX 14.9332 76.2000 75.4814 529.486  2 −66.1089 CC 24.8307 CC  4.3246 75.4814 43.9736 516.496 29.4352 41.8311  0.3201 41.7886  0.1000  3 53.6324 CX −135.5405 CX 12.7000 41.2286 37.9433 883.407 23.5438 APERTURE STOP 12.6896  0.1000  4 53.4713 CX −17.3470 CX  3.3983 13.0472 12.5178 792.470  5 −17.3470 CC 3614.6113 CC  2.7189 12.5178 12.7310 851.250  0.1083  6 56.5631 CX 21.5203 CC  4.7545 12.7797 12.5843 733.271  0.8774  7 93.8769 CX INF  0.9132 12.6457 12.7496 882.407  8 INF −16.3311*1  2.5133*7 12.7496 13.0000 883.407  9 −16.3311*1 INF 11.4872*8 13.0000 21.2039 WATER 10 INF −39.6155 CX 12.7000 21.2039 25.9244 847.238 24.6157 37.5833  1.7944 11 82.6789 CX −54.4438 CX  6.9141 39.8387 39.8600 883.407  0.6380 12 24.4005 CX 0.2545E+19 CC 12.7000 33.0247 26.4655 761.481 13 0.2545E+19 CX 29.6602*2 10.5993*3 26.4655 14.0000 853.258 14 29.6602*2 INF  2.7848*4 14.0000 13.1675 WATER 15 INF 11.9031 CC  0.7000 13.1675 11.4289 883.407  1.1493 16 35.0371 CX −6.9478 CX  4.9112 11.3439 10.3641 776.411 17 −6.9478 CC −17.1013 CX  3.8852 10.3641 9.5151 769.266  0.5538 18 −10.8006 CC −605.6155 CX  2.6619 9.4111 9.8597 847.238  3.9283 19 −26.9946 CC −22.6267 CX  1.7065 13.2013 14.5679 807.463 20 −22.6267 CC −21.1302 CX  0.9799 14.5679 15.4223 WATER 21 −21.1302 CC −14.2521 CX  3.4350 15.4223 17.4510 824.447 22 −14.2521 CC −100.4102 CX  0.7000 17.4510 21.0008 637.321  0.3111 23 −136.9536 CC −24.4945 CX  5.5394 21.9077 24.5712 805.464  0.1000 24 −76.9288 CC −41.9147 CX  1.7746 26.5313 26.9615 883.407  0.1000 28.2597  0.0000 28.2597  0.0000 28.2597 16.3639*5 25 263.0367 CX −50.9828 CX  5.1315 38.1680 38.3247 841.434  0.1000 26 73.5995 CX −258.5643 CX  5.1528 36.6246 35.7766 815.455  0.8365 27 −130.3658 CC 4757.9448 CC  2.2385 35.5682 34.4091 755.268 28 4757.9448 CX 17.0943 CC  0.7000 34.4091 30.1374 WATER 29 17.0943 CX −49.3474 CX 12.4524 30.1374 29.2577 ‘OIL_C300’ 30 −49.3474 CC 18.5795 CC  4.5002 29.2577 23.9988 798.289  2.9395*6 31 33.0053 CX 81.7063 CC  3.0677 26.0000 26.0000 804.466 32 81.7063 CX −26.0223 CX  5.1172 26.0000 26.0000 WATER 33 −26.0223 CC 14.5225 CC  0.7000 26.0000 26.0000 ‘OIL_C300’ 34 14.5225 CX A(2)  8.1909 26.0000 26.0000 SFPL53 Ohara  4.9203 28.0169 IMAGE DISTANCE =  0.0000 IMAGE INF 28.0169 NOTES Positive radius indicates the center of curvature is to the right Negative radius indicates the center of curvature is to the left Dimensions are given in millimeters Thickness is axial distance to next surface Image diameter shown above is a paraxial value, it is not a ray traced value Other glass suppliers can be used if their materials are functionally equivalent to the extent needed by the design; contact the designer for approval of substitutions. ASPHERIC CONSTANTS $Z = {\frac{({CURV})Y^{2}}{1 + \left( {1 - {\left( {1 + K} \right)\mspace{11mu} {({CURV})\;}^{2}Y^{2}}} \right)^{1/2}} + {(A)Y^{4}} + {(B)Y^{6}} + {(C)Y^{8}} + {(D)Y^{10}}}$ ASPHERIC CURV K A B C D A(1) 0.00260273 0.000000 −7.20011E−07   8.40662E−10 −1.23033E−13 0.00000E+00 A(2) 0.03362748 0.000000   2.12757E−06 −2.27939E−07   1.81726E−10 0.00000E+00 REFERENCE WAVELENGTH = 546.1 NM SPECTRAL REGION = 486.1 − 587.6 NM POS. 1 POS. 2 POS. 3 POS. 4 * ZOOM PARAMETERS *1 = −16.3311 −31.0479 600.3563 56.0546 *2 = 29.6602 155.8804 −32.6266 −16.0120 *3 = 10.5993 12.5712 11.9191 12.7000 *4 = 2.7848 0.8268 1.4874 0.7000 *5 = 16.3639 17.0671 8.4560 0.1000 *6 = 2.9395 2.2708 10.7583 19.2651 *7 = 2.5133 1.3880 3.3317 1.3110 *8 = 11.4872 12.6163 10.6755 12.7000 INFINITE CONJUGATES EFL = −20.0878 −25.9451 −40.0379 −55.7271 BFL = 0.0954 −0.0130 −0.0410 0.0934 FFL = 41.0941 32.3346 7.1791 −29.6701 F/NO = −2.9498 −3.3497 −4.4492 −4.9484 AT USED CONJUGATES REDUCTION = −0.0001 −0.0001 −0.0002 −0.0002 FINITE F/NO = −2.9500 −3.3500 −4.4500 −4.9500 OBJECT DIST = 254537.4546 254537.4546 254537.4546 254537.4546 TOTAL TRACK = 254832.2765 254832.3286 254832.2165 254832.3645 IMAGE DIST = 0.0000 0.0000 0.0000 0.0000 OAL = 294.8219 294.8740 294.7619 294.9099 PARAXIAL IMAGE HT = 14.0873 14.5930 13.9705 13.7058 IMAGE DIST = 0.0969 −0.0103 −0.0347 0.1056 SEMI-FIELD ANGLE = 35.0399 29.3540 19.2322 13.8130 ENTR PUPIL DIAMETER = 6.8098 7.7455 8.9990 11.2617 DISTANCE = 54.4608 54.4608 54.4608 54.4608 EXIT PUPIL DIAMETER = 10.2338 9.0823 7.6203 7.4596 DISTANCE = −30.0928 −30.4361 −33.9449 −36.8194 APER STOP DIAMETER = 7.6111 8.6688 10.0930 12.6896 NOTES FFL is measured from the first surface BFL is measured from the last surface 

1. (canceled)
 2. A variable power optical system with no moving lens groups configured to form a final image of an object, the variable power optical system comprising: an objective lens group on a common optical axis, the objective lens group comprising at least one liquid lens cell having at least two liquids with different refractive properties and at least one variable shape contact surface between the two liquids, with variations in the shape of the contact surface producing a change of optical power in the objective lens group; at least one relay lens group positioned on an image side of the objective lens group along the common optical axis, the at least one relay lens group comprising at least one liquid lens cell having at least two liquids with different refractive properties and at least one variable shape contact surface between the two liquids, with variations in the shape of the contact surface producing a change of optical power in the relay lens group; and a lens with a fixed positive power positioned along the common optical axis between the objective lens group and the at least one relay lens group, wherein the objective lens group forms an intermediate real image on the image side of the objective lens group and an object side of the lens with a fixed positive power, and wherein a change in the optical power in the objective lens group changes a magnification of the intermediate real image and a change in the optical power in the at least one relay lens group changes a magnification of the final image.
 3. The variable power optical system of claim 2, wherein an optical stop is located between the object and the intermediate image.
 4. The variable power optical system of claim 3, wherein an iris is placed substantially at the stop location to provide a variable aperture.
 5. The variable power optical system of claim 2, wherein an optical stop is located between the intermediate image and the final image.
 6. The variable power optical system of claim 5, wherein an iris is placed substantially at the stop location to provide a variable aperture.
 7. The variable power optical system of claim 2, wherein the variable power optical system has a zoom ratio between about 2.8× and about 4.4×.
 8. A camera comprising the variable optical power optical system of claim
 2. 9. A variable power optical system configured to form a final image of an object, the variable power optical system comprising: an objective lens group on a common optical axis, the objective lens group configured to form an intermediate real image on an image side of the objective lens group, the objective lens group comprising at least one liquid lens cell with at least two liquids with different refractive properties and at least one variable shape contact surface between the two liquids, with variations in the shape of the contact surface producing a change of optical power in the objective lens group and a change in a magnification of the intermediate real image; an axially stationary positively powered lens group positioned along the common optical axis on an image side of the intermediate real image; and a relay lens group positioned along the common optical axis on an image side of the axially stationary positively powered lens group, the relay lens group comprising at least one liquid lens cell having at least two liquids with different refractive properties and at least one variable shape contact surface between the two liquids, with variations in the shape of the contact surface producing a change of optical power in the relay lens group and a change in a magnification of the final image; and an axially movable lens group positioned along the common optical axis between the relay lens group and the final image, wherein the final image height above the optical axis is larger than the heights of rim rays above the optical axis at the liquid lens cell variable surface in the objective lens group and the relay lens group.
 10. The variable power optical system of claim 9, wherein the variable power optical system has no moving lens groups.
 11. The variable power optical system of claim 9, further comprising a second relay lens group positioned on an image side of the objective lens group along the common optical axis, the second relay lens group comprising at least one liquid lens cell having at least two liquids with different refractive properties and at least one variable shape contact surface between the two liquids, with variations in the shape of the contact surface producing a change of optical power in the second relay lens group.
 12. The variable power optical system of claim 9, wherein the variable power optical system has a zoom ratio between 2.8× and 4.4×.
 13. The variable power optical system of claim 9, further comprising a control system that controls the at least one variable shape contact surface of the at least one liquid lens cell in the objective lens group.
 14. A camera comprising the variable optical power optical system of claim
 9. 